kinetics - STRUCTURAL ENGINEERING FORUM OF INDIA

Transcription

KSCA-AK (For Use with KSCA Brackets)
P7.4.1
KSUA-AK (For Use with KSUA-1 & KSUA-2 Brackets)
P7.4.2
KSCC-AK (For Use with CCA Brackets)
P7.4.3
KSCC4-AK (For Use with CCA-4 Brackets)
P7.4.4
Selection Information
P7.5
Installation Instructions
P7.6
KINETICS™ Seismic Design Manual
Cable Anchorage Hardware Kits
TABLE OF CONTENTS (CHAPTER P7 – CABLE/WIRE ROPE RESTRAINTS)
PAGE 2 OF 2
DUBLIN, OHIO, USA • MISSISSAUGA, ONTARIO, CANADA
RELEASE DATE: 5/21/04
Toll Free (USA only):
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
www.kineticsnoise.com
[email protected]
DOCUMENT:
P7.0
MEMBER
Kinetics Noise Control © 2003
KSWC U-BOLT CLIP CABLE RESTRAINT KIT (KSCA – KSCA)
PAGE 1 OF 1 - DRAWING # S-90.382-1A
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.1
MEMBER
III
IV
1,635
2,960
3/16
1/4
KSWC-187
KSWC-250
* FOR KSCA BRACKET WELDED
TO STEEL PER S-90.379-1B.
III
III
II
CLASS
A=45°±15°
INSTALLATION
ANGLE
1,175
1,175
955
lbs.
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
475
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSWC RESTRAINT CABLE KIT BY KINETICS.
EACH KIT CONTAINS TWO CABLE ASSEMBLIES.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
SUBMITTAL S-90.385-2A
FOR BOLTING & WELDING
INSTRUCTIONS.
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
825
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.382-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
SUBMITTAL S-90.385-2B
FOR CONCRETE
ANCHOR INSTRUCTIONS.
II
955
1/8
KSWC-125
CLASS
in.
----------------
* MAX.
CABLE
TENSION
lbs.
CABLE
SIZE
MODEL
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
KSGC GRIPPLE CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
RELEASE DATE5/21/04
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.2
MEMBER
in.
1/8
3/16
MODEL
----------------
KSGC-125
KSGC-187
---------------
1,235
CLASS
500
lbs.
III
I
CLASS
430
lbs.
III
I
CLASS
615
250
lbs.
II
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
SEE ATTACHMENT KIT
INSTRUCTIONS.
870
350
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSGC RESTRAINT CABLE KIT BY KINETICS.
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
III
I
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
1,065
A=45°±15°
INSTALLATION
ANGLE
1,235
500
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MAX.
CABLE
TENSION
KSUA U-BOLT CLIP CABLE RESTRAINT KIT (KSUA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.3
MEMBER
II
III
IV
955
1,635
2,960
1/8
3/16
1/4
KSUA-125
KSUA-187
KSUA-250
2,960
1,635
955
lbs.
IV
III
II
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
495
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSUA RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
SUBMITTAL S-90.385-5A FOR
BOLTING INSTRUCTIONS.
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
860
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
A=45°±15°
INSTALLATION
ANGLE
CLASS
in.
----------------
lbs.
CABLE
SIZE
MODEL
* MAX.
CABLE
TENSION
KSLG GRIPPLE CABLE RESTRAINT KIT (KSCA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.4
MEMBER
in.
1/8
3/16
MODEL
----------------
KSLG-125
KSLG-187
---------------
1,235
CLASS
500
lbs.
III
I
CLASS
430
lbs.
III
I
CLASS
615
250
lbs.
II
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
SEE ATTACHMENT KIT
INSTRUCTIONS.
870
350
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSLG RESTRAINT CABLE KIT BY KINETICS.
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
III
I
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
1,065
A=45°±15°
INSTALLATION
ANGLE
1,235
500
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MAX.
CABLE
TENSION
KSCU GRIPPLE CABLE RESTRAINT KIT (KSUA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.5
MEMBER
mm
2
3
5
MODEL
----------------
KSCU-2
KSCU-3
KSCU-4
-------------------
1,235
----------
CLASS
500
250
lbs.
I
III
1,235
-0-
CLASS
500
250
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
III
I
-0-
CLASS
870
350
175
lbs.
615
250
125
lbs.
II
-0-
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSCU RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
II
I
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
1,065
430
215
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MAX.
CABLE
TENSION
KSUG GRIPPLE CABLE RESTRAINT KIT (KSUA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.6
MEMBER
-------------------
250
500
1,235
2
3
5
KSUG-2
KSUG-3
KSUG-4
1,235
500
250
lbs.
III
I
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
III
I
-0-
CLASS
II
I
-0-
CLASS
615
250
125
lbs.
II
-0-
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSUG RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
870
350
175
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
1,065
430
215
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
A=45°±15°
INSTALLATION
ANGLE
----------
CLASS
mm
----------------
lbs.
CABLE
SIZE
MODEL
MAX.
CABLE
TENSION
KSWC U-BOLT CLIP CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.1
MEMBER
in.
1/8
3/16
1/4
----------------
KSWC-125
KSWC-187
KSWC-250
CLASS
II
III
IV
lbs.
955
1,635
2,960
* MAX.
CABLE
TENSION
III
III
II
CLASS
A=45°±15°
INSTALLATION
ANGLE
1,175
1,175
955
lbs.
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
475
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSWC RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
INSTRUCTIONS.
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
825
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.382-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
KSGC GRIPPLE CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
RELEASE DATE5/21/04
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.2
MEMBER
in.
1/8
3/16
MODEL
----------------
KSGC-125
KSGC-187
---------------
1,235
CLASS
500
lbs.
III
I
CLASS
430
lbs.
III
I
CLASS
615
250
lbs.
II
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
SEE ATTACHMENT KIT
INSTRUCTIONS.
870
350
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSGC RESTRAINT CABLE KIT BY KINETICS.
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
III
I
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
1,065
A=45°±15°
INSTALLATION
ANGLE
1,235
500
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MAX.
CABLE
TENSION
KSUA U-BOLT CLIP CABLE RESTRAINT KIT (KSUA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.3
MEMBER
in.
1/8
3/16
1/4
----------------
KSUA-125
KSUA-187
KSUA-250
III
IV
1,635
2,960
2,960
1,635
955
lbs.
IV
III
II
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
A=45°±15°
INSTALLATION
ANGLE
II
CLASS
955
lbs.
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
495
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSUA RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
860
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
* MAX.
CABLE
TENSION
KSLG GRIPPLE CABLE RESTRAINT KIT (KSCA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.4
MEMBER
in.
1/8
3/16
MODEL
----------------
KSLG-125
KSLG-187
---------------
1,235
CLASS
500
lbs.
III
I
CLASS
430
lbs.
III
I
CLASS
615
250
lbs.
II
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
SEE ATTACHMENT KIT
INSTRUCTIONS.
870
350
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSLG RESTRAINT CABLE KIT BY KINETICS.
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
III
I
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
1,065
A=45°±15°
INSTALLATION
ANGLE
1,235
500
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MAX.
CABLE
TENSION
KSCU GRIPPLE CABLE RESTRAINT KIT (KSUA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.5
MEMBER
mm
2
3
5
MODEL
----------------
KSCU-2
KSCU-3
KSCU-4
-------------------
1,235
----------
CLASS
500
250
lbs.
1,235
500
250
lbs.
III
I
-0-
CLASS
870
350
175
lbs.
615
250
125
lbs.
II
-0-
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSCU RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
II
I
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
1,065
430
215
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
III
I
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MAX.
CABLE
TENSION
KSUG GRIPPLE CABLE RESTRAINT KIT (KSUA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.2.6
MEMBER
-------------------
500
1,235
2
3
5
KSUG-2
KSUG-3
KSUG-4
1,235
500
250
lbs.
III
I
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
A=45°±15°
INSTALLATION
ANGLE
----------
III
I
-0-
CLASS
II
I
-0-
CLASS
615
250
125
lbs.
II
-0-
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSUG RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
870
350
175
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
1,065
430
215
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
250
CLASS
mm
----------------
lbs.
CABLE
SIZE
MODEL
MAX.
CABLE
TENSION
KSWC U-BOLT CLIP BULK CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.1
MEMBER
in.
1/8
3/16
1/4
----------------
KSWC-125B
KSWC-187B
KSWC-250B
CLASS
II
III
IV
lbs.
955
1,635
2,960
III
III
II
CLASS
A=45°±15°
INSTALLATION
ANGLE
1,175
1,175
955
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
475
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSCW BULK RESTRAINT CABLE KIT BY KINETICS.
EACH STANDARD KIT CONTAINS ENOUGH
MATERIAL FOR (2) 12 FT. CABLE ASSEMBLIES.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
INSTRUCTIONS.
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
825
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.382-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
* MAX.
CABLE
TENSION
KSQF GRIPPLE BULK CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.2
MEMBER
in.
1/8
3/16
----------------
KSQF-125
KSQF-187
---------------
1,235
CLASS
500
lbs.
III
I
CLASS
III
I
CLASS
615
250
I
III
lbs.
CLASS
II
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSQF BULK RESTRAINT CABLE KIT BY KINETICS.
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
SEE ATTACHMENT KIT
INSTRUCTIONS.
870
350
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
CONCRETE
STRUCTURE
BY OTHERS
1,065
430
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
A=45°±15°
INSTALLATION
ANGLE
1,235
500
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
MAX.
CABLE
TENSION
KSUA U-BOLT CLIP BULK CABLE RESTRAINT KIT (KSUA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.3
MEMBER
in.
1/8
3/16
1/4
MODEL
----------------
KSUA-125B
KSUA-187B
KSUA-250B
II
III
IV
1,635
2,960
CLASS
955
lbs.
* MAX.
CABLE
TENSION
* FOR KSUA-2 BRACKET BOLTED
IV
III
II
CLASS
A=45°±15°
INSTALLATION
ANGLE
2,960
1,635
955
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
475
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSUA BULK RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
825
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
KSCCU U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.4
MEMBER
2960
1/4
----------------
KSCCU-250B
* FOR KSUA BRACKET BOLTED
TO STEEL WITH 1/2" DIA. BOLT.
IV
CLASS
A=45°±15°
INSTALLATION
ANGLE
2960
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
CLASS
2090
lbs.
IV
1480
lbs.
III
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
CONCRETE
STRUCTURE
BY OTHERS
A=45°±15°
INSTALLATION
ANGLE
KSCCU BULK RESTRAINT CABLE KIT BY KINETICS.
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2560
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
lbs.
in.
MODEL
* MAX.
CABLE
TENSION
CABLE
SIZE
KSCCU4 U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA-4 – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.5
MEMBER
in.
1/4
----------------
KSCCU4-250B
2960
lbs.
* FOR CCA-4 BRACKET BOLTED
TO CONCRETE
2960
lbs.
2560
lbs.
2090
lbs.
III
CLASS
1 or 2
ORIENTATION
ORIENTATION 2
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
CONCRETE
STRUCTURE
BY OTHERS
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
FOR CONCRETE
1480
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
ORIENTATION 1
A=45°±15°
INSTALLATION
ANGLE
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
* MAX.
CABLE
TENSION
KSCC U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA – CCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.6
MEMBER
in.
1/4
3/8
1/2
MODEL
----------------
KSCC-250B
KSCC-375B
KSCC-500B
8500
5915
2960
lbs.
* FOR CCA BRACKET WELDED
TO STEEL.
IV
IV
IV
CLASS
A=45°±15°
INSTALLATION
ANGLE
3375
3375
2960
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
V
V
IV
CLASS
6010
4180
2090
lbs.
4250
2955
1480
lbs.
IV
IV
III
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSCC BULK RESTRAINT CABLE KIT BY KINETICS.
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
INSTRUCTIONS.
V
IV
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
6250
5120
2560
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
V
V
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
* MAX.
CABLE
TENSION
KSCC4 U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA-4 – CCA)
International:
Fax:
World Wide Web:
Email:
RELEASE DATE5/21/04
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.7
MEMBER
2960
5915
5915
8500
8500
1/4
3/8
3/8
1/2
1/2
----------------
KSCC4-250B
TO CONCRETE.
3375
6250
5915
5915
2960
lbs.
6095
5250
5915
5020
2560
lbs.
5585
5585
5585
5585
2090
lbs.
IV
IV
IV
IV
III
CLASS
2
1
2
1
1 or 2
ORIENTATION
ORIENTATION 2
CONCRETE
STRUCTURE
BY OTHERS
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
FOR CONCRETE
4250
3520
2955
2955
1470
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
V
V
V
V
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
CONCRETE
STRUCTURE
BY OTHERS
V
V
V
V
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
ORIENTATION 1
A=45°±15°
INSTALLATION
ANGLE
IV
V
V
V
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
V
V
V
V
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
KSCC4-500B
KSCC4-375B
lbs.
in.
MODEL
* MAX.
CABLE
TENSION
CABLE
SIZE
KSWC U-BOLT CLIP BULK CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.1
MEMBER
in.
1/8
3/16
1/4
----------------
KSWC-125B
KSWC-187B
KSWC-250B
II
III
IV
1,635
2,960
CLASS
955
lbs.
III
III
II
CLASS
A=45°±15°
INSTALLATION
ANGLE
1,175
1,175
955
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
475
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSCW BULK RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
INSTRUCTIONS.
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
825
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.382-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
* MAX.
CABLE
TENSION
KSQF GRIPPLE BULK CABLE RESTRAINT KIT (KSCA – KSCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.2
MEMBER
in.
1/8
3/16
----------------
KSQF-125
KSQF-187
---------------
1,235
CLASS
500
lbs.
III
I
CLASS
III
I
CLASS
III
I
CLASS
615
250
lbs.
II
-0-
CLASS
MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSQF BULK RESTRAINT CABLE KIT BY KINETICS.
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
SEE ATTACHMENT KIT
INSTRUCTIONS.
870
350
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
CONCRETE
STRUCTURE
BY OTHERS
1,065
430
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
A=45°±15°
INSTALLATION
ANGLE
1,235
500
lbs.
MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.388-3A
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
MAX.
CABLE
TENSION
KSUA U-BOLT CLIP BULK CABLE RESTRAINT KIT (KSUA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.3
MEMBER
in.
1/8
3/16
1/4
MODEL
----------------
KSUA-125B
KSUA-187B
KSUA-250B
II
III
IV
1,635
2,960
CLASS
955
lbs.
* MAX.
CABLE
TENSION
* FOR KSUA-2 BRACKET BOLTED
IV
III
II
CLASS
A=45°±15°
INSTALLATION
ANGLE
2,960
1,635
955
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
III
II
CLASS
IV
III
II
CLASS
1,480
815
475
lbs.
III
II
I
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
STEEL
STRUCTURE
BY OTHERS
KSUA BULK RESTRAINT CABLE KIT BY KINETICS.
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
2,090
1,155
675
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2,560
1,415
825
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
KSCCU U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.4
MEMBER
in.
1/4
MODEL
----------------
KSCCU-250B
2960
lbs.
* FOR KSUA BRACKET BOLTED
TO STEEL WITH 1/2" DIA. BOLT.
IV
CLASS
A=45°±15°
INSTALLATION
ANGLE
2960
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
IV
CLASS
2090
lbs.
IV
1480
lbs.
III
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
CONCRETE
STRUCTURE
BY OTHERS
A=45°±15°
INSTALLATION
ANGLE
KSCCU BULK RESTRAINT CABLE KIT BY KINETICS.
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
FOR CONCRETE
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
2560
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
IV
CLASS
* MAX.
CABLE
TENSION
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
KSCCU4 U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA-4 – KSUA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.5
MEMBER
in.
1/4
----------------
KSCCU4-250B
2960
lbs.
TO CONCRETE
2960
lbs.
2560
lbs.
2090
lbs.
III
CLASS
1 or 2
ORIENTATION
ORIENTATION 2
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
CONCRETE
STRUCTURE
BY OTHERS
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
FOR CONCRETE
1480
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
ORIENTATION 1
A=45°±15°
INSTALLATION
ANGLE
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.397-1B
FOR END LOOP
INSTRUCTIONS
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
MODEL
* MAX.
CABLE
TENSION
KSCC U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA – CCA)
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.6
MEMBER
in.
1/4
3/8
1/2
MODEL
----------------
KSCC-250B
KSCC-375B
KSCC-500B
8500
5915
2960
lbs.
* FOR CCA BRACKET WELDED
TO STEEL.
IV
IV
IV
CLASS
A=45°±15°
INSTALLATION
ANGLE
3375
3375
2960
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
V
V
IV
CLASS
6010
4180
2090
lbs.
4250
2955
1480
lbs.
IV
IV
III
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
A=45°±15°
INSTALLATION
ANGLE
STEEL
STRUCTURE
BY OTHERS
KSCC BULK RESTRAINT CABLE KIT BY KINETICS.
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
SEE ATTACHMENT KIT
INSTRUCTIONS.
V
IV
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE APPROPRIATE
SUBMITTALS
FOR EQUIPMENT
ATTACH. OPTIONS.
CONCRETE
STRUCTURE
BY OTHERS
6250
5120
2560
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
V
V
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
CABLE
SIZE
* MAX.
CABLE
TENSION
KSCC4 U-BOLT CLIP BULK CABLE RESTRAINT KIT (CCA-4 – CCA)
International:
Fax:
World Wide Web:
Email:
RELEASE DATE5/21/04
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.3.7
MEMBER
5915
5915
8500
8500
3/8
3/8
1/2
1/2
KSCC4-250B
TO CONCRETE.
3375
6250
5915
5915
2960
lbs.
6095
5250
5915
5020
2560
lbs.
5585
5585
5585
5585
2090
lbs.
IV
IV
IV
IV
III
CLASS
2
1
2
1
1 or 2
ORIENTATION
ORIENTATION 2
CONCRETE
STRUCTURE
BY OTHERS
A=45°±15°
INSTALLATION
ANGLE
SEE ATTACHMENT KIT
FOR CONCRETE
4250
3520
2955
2955
1470
lbs.
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=60°
V
V
V
V
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=45°
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
CONCRETE
STRUCTURE
BY OTHERS
V
V
V
V
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=30°
ORIENTATION 1
A=45°±15°
INSTALLATION
ANGLE
IV
V
V
V
IV
CLASS
* MAX.
HORIZONTAL
CABLE
FORCE
@ A=0°
SEE S-90.384-11B
FOR END LOOP
INSTRUCTIONS
V
V
V
V
IV
CLASS
SEE ATTACHMENT KIT
FOR CONCRETE
KSCC4-500B
KSCC4-375B
2960
1/4
----------------
lbs.
in.
MODEL
* MAX.
CABLE
TENSION
CABLE
SIZE
THROUGH BOLTED OR WELDED
BOLT/
MAX. HORIZ.
ANCHOR WELD
FORCE
SIZE
LENGTH ORIENTATION
(ØD)
1
(Lw)
(UNC)
@ A=0°
MODEL
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
KSCA-AK-250
0.25
1.00
570
II
985
II
695
II
405
I
625
II
705
II
695
II
570
II
KSCA-AK-375
0.38
1.25
1,175
III
2,405
III
1,700
III
995
II
1,175
III
1,725
III
1,700
III
1,385
III
KSCA-AK-500
0.50
2.00
1,175
III
2,970
IV
2,970
IV
1,820
III
1,175
III
2,970
IV
2,970
IV
2,540
IV
CLASS
HARDWARE
BY KINETICS.
ORIENTATION
1
A°
NEOPRENE
GROMMET
REQUIRED FOR
KSCA-AK-250/-375
BY KINETICS.
A°
KSCA BRACKET
BY KINETICS.
ORIENTATION
2
DO NOT USE
THIS HOLE!!
OPTIONAL WELD ATTACHMENT
EQUAL TO (1) SIZE (ØD) UNC BOLT.
KSCA
KINETIC
ØD
(Lw) TYP
CABLE
ATTACHMENT
HOLE
STEEL
BY
OTHERS.
A°
T
ANCHORED TO CONCRETE
MODEL
BOLT/
ANCHOR
SIZE
(ØD)
(UNC)
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
KSCA-AK-250
0.25
200
-0-
415
I
255
I
140
-0-
215
-0-
240
-0-
255
I
240
-0-
KSCA-AK-375
0.38
435
I
990
II
560
II
300
I
450
I
520
II
560
II
570
II
KSCA-AK-500
0.50
665
II
1,620
III
865
II
455
I
670
II
785
II
865
II
935
II
NEOPRENE GROMMET REQUIRED
FOR KSCA-AK-250/-375 BY KINETICS.
A°
CONCRETE ANCHOR
BY KINETICS.
ORIENTATION
1
A°
KSCA BRACKET
BY KINETICS.
ORIENTATION
2
DO NOT USE
THIS HOLE!!
KSCA
ØD
KINETIC
FOR ANCHOR EMDEDMENT & EDGE DIST.
SEE "ANCHOR CAPACITIES USED BY KNC
SEISMIC PROGRAMS-WEDGE TYPE
ANCHOR APPLICATIONS".
CONCRETE BY OTHERS.
A°
T
CABLE ATTACHMENT HOLE.
KSCA-AK CABLE ANCHORAGE HARDWARE KIT FOR KSCA BRACKETS
PAGE 1 OF 1 - DRAWING # S-90.385-2A & S-90.385-2B
International:
Fax:
World Wide Web:
Email:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.4.1
MEMBER
MODEL
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
KSUA-AK-250
0.25
1,085
III
625
II
450
I
290
I
540
II
505
II
450
I
360
I
KSUA-AK-375
0.38
2,650
IV
1,530
III
1,095
III
710
II
1,325
III
1,230
III
1,095
III
880
II
KSUA-AK-500
0.50
4,850
IV
2,800
IV
2,010
IV
1,300
III
2,425
IV
2,250
IV
2,010
IV
1,615
III
A°
A°
ORIENTATION
1
CLASS
BOLT/
ANCHOR
SIZE
(ØD)
(UNC)
KSUA CABLE ATTACHMENT
BRACKET BY KINETICS.
KSUA -AK
ATTACHMENT
KIT BY KINETICS.
ORIENTATION
2
ØD
STRUCTURAL STEEL
BY OTHERS.
A°
KSUA CABLE RESTRAINT
KIT BY KINETICS.
T
BOLT/
ANCHOR
SIZE
(ØD)
(UNC)
MODEL
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
KSUA-AK-250
0.25
530
II
260
I
170
-0-
100
-0-
185
-0-
175
-0-
170
-0-
150
-0-
KSUA-AK-375
0.38
1,360
III
575
II
360
I
220
-0-
390
I
380
I
360
I
330
I
KSUA-AK-500
0.50
2,390
IV
885
II
550
II
330
I
580
II
570
II
550
II
510
II
A°
ORIENTATION
1
A°
KSUA -AK
ATTACHMENT KIT
BY KINETICS.
ORIENTATION
2
ØD
45°
CONCRETE
BY OTHERS.
KIT BY KINETICS.
T
KSUA-AK CABLE ANCHORAGE HARDWARE KIT FOR KSUA BRACKETS
International:
Fax:
World Wide Web:
Email:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.4.2
MEMBER
BOLT/
MAX. HORIZ.
ANCHOR WELD
FORCE
SIZE
LENGTH ORIENTATION
(ØD)
1
(Lw)
(UNC)
@ A=0°
MODEL
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
KSCA-AK-250
0.25
1.00
570
II
985
II
695
II
405
I
625
II
705
II
695
II
570
II
KSCA-AK-375
0.38
1.25
1,175
III
2,405
III
1,700
III
995
II
1,175
III
1,725
III
1,700
III
1,385
III
KSCA-AK-500
0.50
2.00
1,175
III
2,970
IV
2,970
IV
1,820
III
1,175
III
2,970
IV
2,970
IV
2,540
IV
CLASS
HARDWARE
BY KINETICS.
ORIENTATION
1
A°
NEOPRENE
GROMMET
REQUIRED FOR
KSCA-AK-250/-375
BY KINETICS.
A°
KSCA BRACKET
BY KINETICS.
ORIENTATION
2
DO NOT USE
THIS HOLE!!
OPTIONAL WELD ATTACHMENT
EQUAL TO (1) SIZE (ØD) UNC BOLT.
KSCA
KINETIC
ØD
(Lw) TYP
CABLE
ATTACHMENT
HOLE
STEEL
BY
OTHERS.
A°
T
MODEL
BOLT/
ANCHOR
SIZE
(ØD)
(UNC)
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
KSCA-AK-250
0.25
200
-0-
415
I
255
I
140
-0-
215
-0-
240
-0-
255
I
240
-0-
KSCA-AK-375
0.38
435
I
990
II
560
II
300
I
450
I
520
II
560
II
570
II
KSCA-AK-500
0.50
665
II
1,620
III
865
II
455
I
670
II
785
II
865
II
935
II
NEOPRENE GROMMET REQUIRED
FOR KSCA-AK-250/-375 BY KINETICS.
A°
CONCRETE ANCHOR
BY KINETICS.
ORIENTATION
1
A°
KSCA BRACKET
BY KINETICS.
ORIENTATION
2
DO NOT USE
THIS HOLE!!
KSCA
ØD
KINETIC
CONCRETE BY OTHERS.
A°
T
CABLE ATTACHMENT HOLE.
KSCA-AK CABLE ANCHORAGE HARDWARE KIT FOR KSCA BRACKETS
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.4.1
MEMBER
MODEL
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
KSUA-AK-250
0.25
1,085
III
625
II
450
I
290
I
540
II
505
II
450
I
360
I
KSUA-AK-375
0.38
2,650
IV
1,530
III
1,095
III
710
II
1,325
III
1,230
III
1,095
III
880
II
KSUA-AK-500
0.50
4,850
IV
2,800
IV
2,010
IV
1,300
III
2,425
IV
2,250
IV
2,010
IV
1,615
III
A°
A°
ORIENTATION
1
CLASS
BOLT/
ANCHOR
SIZE
(ØD)
(UNC)
KSUA -AK
ATTACHMENT
KIT BY KINETICS.
ORIENTATION
2
ØD
STRUCTURAL STEEL
BY OTHERS.
A°
KIT BY KINETICS.
T
BOLT/
ANCHOR
SIZE
(ØD)
(UNC)
MODEL
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
1
@ A=60°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=0°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=30°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=45°
MAX. HORIZ.
FORCE
ORIENTATION
2
@ A=60°
----------------
in.
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
lbs.
CLASS
KSUA-AK-250
0.25
530
II
260
I
170
-0-
100
-0-
185
-0-
175
-0-
170
-0-
150
-0-
KSUA-AK-375
0.38
1,360
III
575
II
360
I
220
-0-
390
I
380
I
360
I
330
I
KSUA-AK-500
0.50
2,390
IV
885
II
550
II
330
I
580
II
570
II
550
II
510
II
A°
ORIENTATION
1
A°
KSUA -AK
ATTACHMENT KIT
BY KINETICS.
ORIENTATION
2
ØD
45°
CONCRETE
BY OTHERS.
KIT BY KINETICS.
T
KSUA-AK CABLE ANCHORAGE HARDWARE KIT FOR KSUA BRACKETS
International:
Fax:
World Wide Web:
Email:
800-959-1229
614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P7.4.2
MEMBER
CHAPTER P8
OTHER REQUIRED COMPONENTS FOR SUSPENDED SYSTEMS
General Description
P8.1
Submittal Data
P8.2
KHRC-A (Rod Stiffener Clamps for Angles)
P8.2.1
KHRC-P (Rod Stiffener Clamps for Pipes)
P8.2.2
KCHB (Pipe Clevis Internal Brace)
P8.2.3
KSCA (Cable/Strut Attachment Bracket)
P8.2.4
KSUA (Optional Cable/Strut Attachment Bracket)
P8.2.5
KSCC (Strut Attachment Clip)
P8.2.6
KSBC (Beam Clamp)
P8.2.7
P8.3
P8.4
KINETICS ™ Seismic Design Manual
TABLE OF CONTENTS
TABLE OF CONTENTS (Chapter P8)
OTHER REQUIRED COMPONENTS FOR SUSPENDED SYSTEMS
International:
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614-889-0540
[email protected]
PAGE:
P8.0
MEMBER
KHRC-A ADJUSTABLE STIFFENER KIT
DRAWING # S-90.500-1A
International:
Fax:
World Wide Web:
Email:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P8.2.1-1
MEMBER
Kinetics Noise Control ©2003
1 .6 3
3 .0 0
K H R C -A
K IN E T IC S
Ø 1 .0 0
MAX.
TYP.
Ø 0 .3 8
M IN .
TYP.
K H R C -A
K IN E T IC S
THUM B SCREW
B Y K IN E T IC S
IN H O LE S # 2
FO R L 2 X 2
ANGLES.
L 2 X 2 X 0 .2 5
L 2 X 2 X 0 .1 3
K H R C -A IN N E R C L A M P
H A L F B Y K IN E T IC S .
H O LE #2
H O LE #1
4 .1 3
H O LE #2
H O LE #1
K H R C -A O U T E R C L A M P
H A L F B Y K IN E T IC S .
2 .2 5
THUM B SCREW
B Y K IN E T IC S
IN H O LE S # 1
FOR L 1 X 1 AND
L 1 .5 X 1 .5 A N G L E .
L 1 .5 X 1 .5 X 0 .2 5
L 1 X 1 X 0 .1 3
DRAWING # S-90.500-1B
International:
Fax:
World Wide Web:
Email:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P8.2.1-2
MEMBER
KHRC-A ADJUSTABLE
ANGLE STIFFENER
KIT BY KINETICS.
STIFFENER ANGLE
BY OTHERS. SIZE
RECOMMENDED ON
TABLE 4b OF
KINETICS "SITE
SPECIFIC FORCE
CLASS TABLES".
CLEVIS HANGER
BY OTHERS.
L1
L2
L3
KSWC CABLE
RESTRAINT
KIT SHOWN
BY KINETICS.
KCHB CLEVIS
HANGER BRACE
KIT SHOWN BY
KINETICS.
1.) THE VALUES OF L2 AND (L1+L3) MUST
NOT EXCEED THE MAXIMUM UNSTIFFENED
HANGER ROD LENGTH FROM TABLE 4b OF
KINETICS "SITE SPECIFIC FORCE CALSS
TABLES".
2.) A MINIMUM OF TWO (2) KHRC-A'S ARE
REQUIRED PER HANGER ROD INSTALLATION.
IMPORTANT NOTES:
THREADED
HANGER
ROD BY
OTHERS.
COUPLING &
ANCHOR BY
OTHERS.
KHRC-A
KINETICS
KHRC-A
KINETICS
KHRC-A
KINETICS
DRAWING # S-90.500-1C
International:
Fax:
World Wide Web:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P8.2.1-3
MEMBER
0.25 MAX.
KHRC-A ADJUSTABLE
ANGLE STIFFENER
KIT BY KINETICS.
STIFFENER ANGLE
BY OTHERS. SIZE
RECOMMENDED ON
TABLE 4b OF
KINETICS "SITE
SPECIFIC FORCE
CLASS TABLES".
ISOLATION BY
KINETICS
0.38 MAX.
CLEVIS HANGER
BY OTHERS.
L1
L2
KSWC CABLE
RESTRAINT
KIT SHOWN
BY KINETICS.
KCHB CLEVIS
HANGER BRACE
KIT SHOWN BY
KINETICS.
1.) THE VALUES OF L2 AND (L1+L3) MUST
NOT EXCEED THE MAXIMUM UNSTIFFENED
HANGER ROD LENGTH FROM TABLE 4b OF
KINETICS "SITE SPECIFIC FORCE CALSS
TABLES".
2.) A MINIMUM OF TWO (2) KHRC-A'S ARE
REQUIRED PER HA NGER ROD INSTALLATION.
IMPORTANT NOTES:
THREADED
HANGER
ROD BY
OTHERS.
VERTICAL LIMIT
STOP @ ALL
RESTRAINT
LOCATIONS.
K HR C-A
KI NE TIC S
K HR C-A
KI NE TIC S
K HR C-A
KI NE TIC S
L3
KCHB CLEVIS HANGER BRACE
DRAWING # S-90.600-1A
International:
Fax:
World Wide Web:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P8.2.3-1
MEMBER
A
0 .6 9
30"
E A C H K IT C O N T A IN S (2 ).
0 .3 8
24"
16"
K C H B -1 7
14"
K C H B -1 2
K C H B -1 3
K C H B -1 6
12"
K C H B -1 1
18"
10"
K C H B -1 0
20"
8"
K C H B -0 9
K C H B -1 5
6"
K C H B -0 8
K C H B -1 4
4"
5"
K C H B -0 7
K C H B -0 5
K C H B -0 6
3"
3 -1 / 2 "
K C H B -0 4
2"
2 -1 / 2 "
K C H B -0 2
1 -1 / 2 "
K C H B -0 1
K C H B -0 3
P IP E S IZ E
MODEL
K C H B B R A C E A N G LE S T R A P
6 .3 8
P E R M O D E L D E S C R IP TIO N
IN T A B L E A T T H E R IG H T .
E A C H K IT C O N T A IN S (1 )
KCHB BRAC E ANGLE
ØD
L
1 .0 0
1 .0 0
1 .0 0
1 .0 0
1 .0 0
30.00
24.00
20.00
18.00
16.00
14.00
12.75
1 .0 0
10.75
0 .7 5
8 .6 3
6 .6 3
5 .5 6
4 .5 0
4 .0 0
3 .5 0
0 .7 5
0 .7 5
0 .7 5
0 .7 5
0 .7 5
0 .5 0
0 .5 0
0 .8 8
0 .8 8
0 .8 8
0 .8 8
0 .8 8
0 .8 8
0 .5 0
0 .5 0
0 .5 0
0 .5 0
0 .5 0
0 .5 0
0 .2 5
0 .2 5
0 .2 5
0 .2 5
2 .8 8
2 .3 8
0 .5 0
0 .5 0
0 .2 5
1 .2 5
1 .2 5
1 .2 5
1 .2 5
1 .2 5
1 .2 5
0 .7 5
0 .7 5
0 .7 5
0 .7 5
0 .7 5
0 .7 5
0 .3 8
0 .3 8
0 .3 8
0 .3 8
0 .3 8
ØD m in. ØD m a x .
(in.)
(in.)
1 .8 8
L
(in.)
0 .5 0
A
(in.)
KCHB CLEVIS HANGER BRACE
DRAWING # S-90.600-1B
International:
Fax:
World Wide Web:
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614-889-0480
614-889-0540
[email protected]
DOCUMENT:
P8.2.3-2
MEMBER
STRAP AROUND ANGLE &
BOLT AS SHOWN ABOVE.
WRAP EXCESS ANGL E BRACE
STEP 2:
CLEVIS
HANGER
BY OTHERS
KCHB CLEVIS
HANGER BRACE
KIT BY KINETICS
KCHB BRACE
ANGLE (1)
PER KIT BY
KINETICS.
CLEVIS HANGER BOLT. WRAP
BRACE ANGLE STRAP AROUND
ANGLE & BOLT. THREAD STRAP
THROUGH SLOT, PULL TIGHT,
AND BEND AS SHOWN ABOVE.
POSITION BRACE ANGLE ON
STEP 1:
KCHB BRACE ANGLE
STRAP (2) PER
KIT BY KINETICS.
KSWC CABLE
RESTRAINT KIT
BY KINETICS
5" SCHED. 40
PIPE SHOWN.
5/8-11 UNC
HANGER ROD
SHOWN BY
OTHERS.
Kinetics KSBC Seismically Rated Beam Clamp
Before proceeding in the selection of a beam clamp, first determine that the beams to
which the restraint is to be attached are oriented properly. All connections must be
positive and not rely on friction to carry the seismic load. This means that the direction of
the cable and/or strut used to resist the forces must be at right angles to the beam. If the
cable or strut is oriented in line with the beam axis, a beam clamp cannot be used and a
weld-on tab or bolted connection is required.
If, based on the above, it is possible to use a beam clamp, an appropriate type and size
must be selected. Most commercially available Beam Clamps are not appropriate for the
attachment of restraints as they are designed to support vertical loads and not transfer
horizontal ones. Unless rated for horizontal loads by the manufacturer, “conventional”
beam clamps should not be used. As a minimum, appropriate beam clamps must meet
the following set of requirements:
1) Beam clamps must engage both sides of a beam such that, even if the attachment bolt
is not fully tightened, there is no possibility that the clamp can be pulled off of the
beam.
2) Both the clamp bracket itself and the arm that engages the opposite side of the beam
must be adequate to transfer the full horizontal load that is required for the application
3) The hardware used to attach the restraint or strut bracket to the beam clamp must also
be adequate to transfer the full horizontal load that is required for the application.
4) All components used must be rated using factors consistent with code requirements
and appropriate for seismic design.
The Kinetics Noise Control KSBC Beam Clamp is designed to address the horizontal
loads expected from seismic events. The two (2) sizes available use 3/8” and 1/2”
attachment hardware and are equivalent to full bolted connections for hardware of the
same size. (Thus if documentation requires that a 3/8” bolt be used, a 3/8” beam clamp is
equally acceptable.)
There is frequently a desire to attach seismic restraints to roof or floor support I-beams.
Equally often the ability to add holes to these beams for bolts or to weld tabs to them is
not possible or practical. In these conditions, Beam Clamps can often be used as long as
they are of the proper type, are properly sized and are properly installed.
Note that, as with any seismic connection to structural elements, the ability of the
structural element to resist the design seismic load is known only by the structural
engineer of record. As these forces can be significant and because beams used to
support structures are typically designed around the vertical or gravity loads, there may be
structural issues that must be addressed when connecting to and applying large
horizontal forces to these members. Always, before connecting restraints to beams or
KSBC Beam Clamp
PAGE 1 OF 4
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P8.2.7
7
MEMBER
other structural elements, ensure that the capacity of the elements to resist these loads is
adequate. Kinetics Noise Control is not in a position to accept any responsibility for
problems that develop from restraints being attached to inadequate structural elements.
3/8" X 2" LONG
HEX HEAD B OLT
3/8" HEX NUT
3/8" ALL THREAD
KSBC-1 ASSEMBLY
Typical KSBC shown with KSUA attachment clip
(Can also be used with KSCA clip)
KSBC Beam Clamp
PAGE 2 OF 4
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P8.2.7
7
MEMBER
APPROX.
2" TALL
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3/8" X 2" LONG
HEX HEAD BOLT
KSCA
SEE DRAWING
S-90.379-1A
KINETICS SEISMIC BEAM CLAMP
ASSEMBLY DOES NOT INCLUDE
THESE BRACKETS. SHOWN FOR
OPTIONAL ASSEMBLIES ONLY.
KSBC-2 ASSEMBLY
MINUMUM CLAMPING WIDTH = 3"
MAXIMUM CLAMPING WIDTH = 9"
I-BEAM
(BY OTHERS)
APPROX.
3 1/4" TALL
KSBC Beam Clamp
DOCUMENT:
P8.2.7
7
MEMBER
KSUA-2
SEE DRAWING
S-90.379-5A
FOR 1/2" ROD
1/2" ALL THREAD
1/2" FLAT WASHER
APPROX.
2" TALL
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3/8" X 2" LONG
HEX HEAD BOLT
KSCA
SEE DRAWING
S-90.379-1A
KINETICS SEISMIC BEAM CLAMP
ASSEMBLY DOES NOT INCLUDE
THESE BRACKETS. SHOWN FOR
OPTIONAL ASSEMBLIES ONLY.
KSBC-1 ASSEMBLY
MINUMUM CLAMPING WIDTH = 3"
MAXIMUM CLAMPING WIDTH = 9"
I-BEAM
(BY OTHERS)
APPROX.
3" TALL
KSBC Beam Clamp
DOCUMENT:
P8.2.7
7.3
MEMBER
KSUA-1
SEE DRAWING
S-90.379-5A
FOR 3/8" ROD
3/8" ALL THREAD
3/8" HEX NUT
3/8" FLAT WASHER
TABLE OF CONTENTS
ARCHITECTURAL RESTRAINT ELEMENTS
P9.1
Floating Floor Submittal Data
FFR-1 (Embedded Floor Restraint)
P9.2.1
FFR-2 (Embedded Floor Restraint)
P9.2.2
PERIMETER PADS
P9.2.3
Isolated Ceiling Component Submittal Data
KSWC Cable Kits
P9.3.1
Isolated Wall Component Submittal Data
PSB (Wall Sway Brace)
P9.4.1
IPRB (Wall Restraint Angle Clip [Top Edge])
P9.4.2
KSWB (Neoprene Resilient Wall Clip)
P9.4.3
P9.5
P9.6
General Description
FLOATING FLOOR RESTRAINTS
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P9.0
MEMBER
FFR-1 FLOOR RESTRAINT (LIFT SLAB)
PAGE 1 OF 1 - DRAWING # SS-20000202
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P9.2.1
MEMBER
FFR-2 FLOOR RESTRAINT (ROLL OUT SYSTEM)
PAGE 1 OF 1 - DRAWING # SS-20000203
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DOCUMENT:
P9.2.2
MEMBER
ANCHOR BOLTS AND ATTACHMENT HARDWARE
General Description
P10.1
Submittal Data
P10.2
KCAB Anchor Bolts (Wedge-Type Anchors)
P10.2.1
KUAB Anchor Bolts (Undercut Anchors)
P10.2.2
TG Grommets (Oversized Holes and Cushioned Anchorage)
P10.2.3
P10.3
KCAB Wedge Type Anchor Selection Guide
P10.3.1
KUAB Undercut type Anchor Selection Guide
P10.3.2
P10.4
TABLE OF CONTENTS
ANCHOR BOLTS AND ATTACHMENT HARDWARE
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P10.0
MEMBER
KCAB Wedge Type Seismic Anchor Data
The data provided in Table P10.2.1-1 is based on concrete with a minimum compressive
strength of 3,000 psi and a minimum embedment depth equal to 8 anchor diameters.
Table P10.2.1-1: KCAB Wedge Type Seismic Anchor Basic Capacities
(Reference: Figure P10.2.1-1)
Basic
Basic
Minimum
Anchor
Minimum
ASD
ASD
Minimum
Edge
Spacing2
Size3 Embedment
Shear
Tensile
Distance2
Allowable1 Allowable1
(in)
(in)
(in)
(in)
(lbs)
(lbs)
1/4
2
280
400
4
3-3/8
3/8
3
588
1,018
6
4-7/8
1/2
4
874
1,769
7
6-3/4
5/8
5
1,317
2,640
8
8-1/4
3/4
6
1,668
4,225
10-1/4
9-3/4
7/8
7
2,264
6,210
12-5/16
9-1/8
1
8
2,535
8,328
14-5/8
13-1/2
1
9
2,730
8,328
12
13-1/2
1-1/4
10
5,105
9,918
15
12-15/16
The Seismic Certification programs written and used by Kinetics Noise Control use the
model KCAB Wedge Type Anchor data listed in Table P10.2.1-1 below. The various
terms and dimensions referenced in this document are defined in Figure P10.2.1-1. Any
anchors that are substituted and/or supplied by others must be evaluated and approved
by the Design Professional of Record. The data listed in Table P10.2.1-1 is drawn form
ICBO report data. All relevant factors for proper installation of these anchors are defined
in documentation provided by Kinetics Noise Control.
1) For Non-California projects these values may be inflated by 33-1/3% for seismic and wind
applications. For California Non-OSHPD projects these values must be reduced by 20%. For
California OSHPD projects the allowable loads for lightweight, 2,000 psi, concrete must be
reduced by 20% to simulate cracked concrete. In this case the values listed here do not apply.
2) Minimum spacing and edge distance are required to develop the maximum listed allowable
loads.
3) If the Clearance Hole Diameter is greater than or equal to 1/8 more than the Anchor Size, fill
the clearance space with grout or epoxy, or use the appropriate Kinetics Noise Control model TG
Grommet.
KCAB WEDGE TYPE SEISMIC ANCHOR DATA
PAGE 1 OF 3
DUBLIN, OHIO, USA •MISSISSAUGA, ONTARIO, CANADA
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P10.2.1
MEMBER
Min.
Cover
Anchor
Length
Clearance
Hole Dia.
Min.
Embedment
Slab/
Housekeeping
Pad
Thickness
Min.
Edge
Dist.
Length Code
Stamped Here
Min.
Spacing
Mounting
Plate/Foot
Anchor Size
Figure P10.2.1-1: KCAB Wedge Type Seismic Anchor Installation Guide.
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P10.2.1
MEMBER
Length
Code
Stamp
Anchor Length
(in)
Length
Code
Stamp
Anchor Length
(in)
A
B
C
D
E
F
G
H
I
J
1.5 to 2.0
2.0 to 2.5
2.5 to 3.0
3.0 to 3.5
3.5 to 4.0
4.0 to 4.5
4.5 to 5.0
5.0 to 5.5
5.5 to 6.0
6.0 to 6.5
K
L
M
N
O
P
Q
R
S
----------
6.5 to 7.0
7.0 to 7.5
7.5 to 8.0
8.0 to 8.5
8.5 to 9.0
9.0 to 9.5
9.5 to 10.0
10.0 to 11.0
11.0 to 12.0
---------------
Table P10.2.1-3: Anchor Size vs. Tightening Torque for Standard Weight Concrete
Anchor
Size
(in)
Anchor
Tightening
Torque
(ft-lbs)
1/4
3/8
1/2
5/8
3/4
7/8
1
8.00
25.00
55.00
90.00
175.0
250.0
300.0
Table P10.2.1-4: Minimum Cover Requirements per ACI 318-02
Minimum
Cover
(in)
Concrete Exposure Condition
Cast-in-Place & Nonprestressed
3
1-1/2
3/4
1-1/2
3/4
Cast-in-place and permanently exposed to the ground.
Exposed to the ground or weather.
Slabs, walls, or joists not exposed to the weather or ground.
Beams or Columns not exposed to the weather or ground.
Shells or folded plate members not exposed to the weather or ground.
Table P10.2.1-2: Anchor Length by Length Code Stamp (Anchor Size Independent)
PAGE 3 OF3
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DOCUMENT:
P10.2.1
MEMBER
The Seismic Certification programs written and used by Kinetics Noise Control use the
model KUAB Type P Undercut Anchor data listed in Tables P10.2.2-1, P10.2.2-2, and
P10.2.2-3 below. Type P indicates that the anchor is a pre-setting or pre-positioning
type of anchor. The various terms and dimensions referenced in this document are
defined in Figures P10.2.2-1, P10.2.2-2, and P10.2.2-3. Any other anchors that are
substituted and/or supplied by others must be evaluated and approved by the Design
Professional of Record. The data listed in Tables P10.2.2-1 through P10.2.2-3 is drawn
from ICC ES Report ESR-1546 (Issued August 1, 2004). All relevant factors for proper
installation of these anchors are defined in documentation provided by Kinetics Noise
Control.
The values in Table P10.2.2-1 are based on normal-weight concrete with a compressive
strength of 3,000 psi, and are adjusted for seismic and wind loading applications in
accordance with the provisions established in ACI 318-02 Appendix D.
Table P10.2.2-1: KUAB Type P Undercut Seismic Anchor Capacities.
Undercut
Anchor
Model
Anchor
Size1
mm
(in)
Req.
Embed.2
mm
(in)
Seismic
Tensile
Allow.
ASD3
N
(lbs)
Seismic
Shear
Allow.
ASD3
N
(lbs)
Req.
Spacing2
mm
(in)
Req.
Edge
Dist.2
mm
(in)
Length
Code
Stamp
KUAB-01
M10
(3/8)
100
(3.94)
19,424
(4,365)
8,869
(1,993)
300
(11.81)
150
(5.91)
I
KUAB-02
M12
(1/2)
125
(4.92)
24,284
(5,457)
12,856
(2,889)
375
(14.76)
188
(7.38)
L
KUAB-03
M16
(5/8)
190
(7.48)
48,567
(10,914)
23941
(5,380)
570
(22.44)
285
(11.22)
R
KUAB-04
M20
(3/4)
250
(9.84)
72,851
(16,371)
36797
(8,269)
750
(29.53)
375
(14.76)
V
KUAB Type P Undercut Seismic Anchor Data
1 - If the Clearance Hole Diameter is greater than or equal to 1/8 more than the Anchor Size, fill
the clearance space with grout or epoxy, or use the appropriate Kinetics Noise Control model
TG Grommet.
2 - Required embedment, spacing, and edge distance are required to develop the maximum
listed allowable loads.
3 - These values may not be inflated by 33-1/3% for seismic and wind applications!
KUAB TYPE P UNDERCUT SEISMIC ANCHOR DATA
PAGE 1 OF 3
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P10.2.2
MEMBER
Req.
Spacing
H=
Req. Embed.
+
Cover
Req.
Edge
Dist.
Req.
Edge
Dist.
Mounting
Plate/Foot
Figure P10.2.2-1: KUAB Type P Undercut Seismic Anchor Placement Guide.
Table P10.2.2-2: KUAB Type P Undercut Seismic Anchor Dimensional Data.
Undercut
Anchor
Model
Anchor
Size
mm
(in)
A
mm
(in)
B
mm
(in)
C
mm
(in)
D
mm
(in)
E
mm
(in)
F
mm
(in)
G
mm
(in)
H
mm
(in
Length
Code
Stamp
KUAB-01
M10
(3/8)
20
(0.79)
107
(4.21)
20
(0.79)
12
(0.47)
10
(0.39)
17
(0.67)
27.5
(1.08)
170
(6.69)
I
KUAB-02
M12
(1/2)
22
(0.87)
135
(5.31)
30
(1.18)
14
(0.55)
12
(0.47)
19
(0.75)
33.5
(1.32)
190
(7.48)
L
KUAB-03
M16
(5/8)
30
(1.18)
203
(7.99)
40
(1.57)
18
(0.71)
16
(0.63)
24
(0.94)
45.5
(1.79)
270
(10.63)
R
KUAB-04
M20
(3/4)
37
(1.46)
266
(10.47)
50
(1.97)
22
(0.87)
20
(0.79)
30
(1.18)
50
(1.97)
350
(13.78)
V
Length Code
Stamp
PAGE 2 OF 3
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P10.2.2
MEMBER
ØG - Washer Dia.
F - Across Flats
C - Max. Grip
ØD
Clearance
Hole
B - Min.
Drill Depth
H - Min.
Concrete
Thickness
ØA - Drill Dia.
Figure P10.2.2-2: KUAB Type P Undercut Seismic Anchor Installation Guide.
Table P10.2.2-3: Anchor Size vs. Tightening Torque for Standard Weight Concrete.
Undercut
Anchor
Model
Anchor
Size
mm
(in)
Anchor
Tightening
Torque
N-m
(ft-lbs)
Length
Code
Stamp
KUAB-01
M10
(3/8)
50
(37)
I
KUAB-02
M12
(1/2)
80
(59)
L
KUAB-03
M16
(5/8)
120
(88)
R
KUAB-04
M20
(3/4)
300
(221)
V
ØE - Stud Dia.
PAGE 3 OF 3
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P10.2.2
MEMBER
The Kinetics Noise Control model TG Bolt Isolation Grommet is used primarily to fill the
excess clearance in the anchor/bolt holes in equipment/isolator mounting plates/feet. The
codes and best practice require that the diameter of an anchor/bolt hole not exceed the
diameter of the anchor/bolt by more than 1/8 inch. In many cases, the seismic analysis
will indicate that an anchor/bolt of smaller size than that provided for in the mounting
plate/foot may be used for a specific application. The Kinetics Noise Control model TG
Bolt Isolation Grommet may be used in these cases to bring the anchor/bolt hole
clearance into line with the code and best practice recommended clearance for the
smaller anchor/bolt size. In order to perform satisfactorily in this type of application, the
material used for the model TG Bolt Isolation Grommet is 80 Durometer Neoprene. A
typical Kinetics Noise Control model TG Bolt Isolation Grommet is shown below in
Figure P10.2.3-1. The dimensional data for the product family line is given in Tables
P10.2.3-1 and P10.2.3-2. A typical TG Bolt Isolation Grommet Installation is shown in
Figure P10.2.3-2.
Size
(in)
Model No.
TG-25
KINETICS®
1/4
ØB
ØA
C
TG Bolt Isolation Grommet Submittal Data
ØE
D
80 Durometer
Neoprene
Figure P10.2.3-1: Typical Model TG Bolt Isolation Grommet.
TG BOLT ISOLATION GROMMET SUBMITTAL DATA
PAGE 1 OF 3
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P10.2.3
MEMBER
Table P10.2.3-1: TG Bolt Isolation Grommet English Dimensional Data.
Model
Anchor/
Bolt
Size
(in)
TG-25
1/4
1.00 0.25 0.13 0.38 0.50
TG-38
3/8
1.25 0.38 0.13 0.50 0.63
TG-50
1/2
1.63 0.50 0.13 0.50 0.75
TG-63
5/8
2.00 0.63 0.19 0.63 0.88
TG-75
3/4
2.25 0.75 0.19 0.63 1.00
TG-100
1
2.75 1.00 0.25 0.88 1.25
TG-125
1-1/4
3.25 1.25 0.25 0.88 1.50
TG-150
1-1/2
3.75 1.50 0.25 1.00 1.75
B
(in)
C
(in)
D
(in)
E
(in)
A
(in)
Table P10.2.3-2: TG Bolt Isolation Grommet Metric Dimensional Data.
Model
Anchor/
A
B
C
D
E
Bolt
(mm) (mm) (mm) (mm) (mm)
Size
(in)
TG-25
1/4
25.4
6.4
3.2
9.5
12.7
TG-38
3/8
31.8
9.5
3.2
12.7
15.9
TG-50
1/2
41.3
12.7
3.2
12.7
19.1
TG-63
5/8
50.8
15.9
4.8
15.9
22.2
TG-75
3/4
57.2
19.1
4.8
15.9
25.4
TG-100
1
69.9
25.4
6.4
22.2
31.8
TG-125
1-1/4
82.6
31.8
6.4
22.2
38.1
TG-150
1-1/2
95.3
38.1
6.4
25.4
44.4
PAGE 2 OF 3
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DOCUMENT:
P10.2.3
MEMBER
ANCHOR/BOLT
MODEL TG BOLT
ISOLATION GROMMET
MOUNTING
PLATE/FOOT
OVERSIZED HOLE
IN MOUNTING
PLATE/FOOT
Figure P10.2.3-2: Typical TG Bolt Isolation Grommet Installation.
PAGE 3 OF 3
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P10.2.3
MEMBER
KCCAB CRACKED CONCRETE WEDGE TYPE SEISMIC ANCHOR DATA
1,102
691
999
1/2
4
3 1/4
2,386
1,706
5/8
4 3/4
4
2,835
3/4
5 3/4
4 3/4
4,272
Anchor Size (in)
Minimum Concrete
Thickness (in)
2
Critical Anchor Edge
Distance (in)
Allowable Shear Load
(ASD) (lbs)
2 5/8
Critical Anchor Spacing
(in)
Allowable Combined
Load (ASD) (lbs)
3/8
Pilot Hole Depth (in)
Allowable Tensile Load
(ASD) (lbs)
Anchor Embedment (in)
Table P10.2.4-1; Model KCCAB Anchor Capacities – Standard Embedment in 3,000 psi Normal
Weight Concrete
6
4 3/8
4
2,839
9 3/4
7 1/2
6
2,284
4,678
12
8 3/4
6
3,321
6,313
14 1/4
9
8
4,500
3/8 Anchor
4,000
1/2 Anchor
Vertical Load (lbs)
3,500
5/8 Anchor
3,000
3/4 Anchor
2,500
2,000
1,500
1,000
500
0
0
500 1,000 1,500 2,000 2,500 3,000 3,500 4,000 4,500 5,000 5,500 6,000 6,500 7,000
Horizontal Load (lbs)
Figure P10.2.4-1; Seismic Capacity Envelopes for Model KCCAB Concrete Anchors with
Standard Embedment
PAGE 1 of 3
SECTION – P10.2.4
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RELEASED ON: 08/07/2008
Member
Min.
Cover
Anchor
Length
Clearance
Hole Dia.
Min.
Embedment
Min.
Edge
Dist.
Slab/
Housekeeping
Pad
Thickness
Mounting
Plate/Foot
Anchor Size
Min.
Spacing
Length Code
Stamped Here
Figure P10.2.4-2; KCCAB Cracked Concrete Seismic Anchor Installation Guide
PAGE 2 of 3
SECTION – P10.2.4
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Member
Table P10.2.4-2: Anchor Length by Length Code Stamp (Anchor Size Independent)
Length
Code
Stamp
Anchor Length
(in)
Length
Code
Stamp
Anchor Length
(in)
A
B
C
D
E
F
G
H
I
J
K
L
1.5 up to 2.0
2.0 up to 2.5
2.5 up to 3.0
3.0 up to 3.5
3.5 up to 4.0
4.0 up to 4.5
4.5 up to 5.0
5.0 up to 5.5
5.5 up to 6.0
6.0 up to 6.5
6.5 up to 7.0
7.0 up to 7.5
M
N
O
P
Q
R
S
T
U
V
W
----------
7.5 up to 8.0
8.0 up to 8.5
8.5 up to 9.0
9.0 up to 9.5
9.5 up to 10.0
10.0 up to 11.0
11.0 up to 12.0
12.0 up to 13.0
13.0 up to 14.0
14.0 up to 15.0
15.0 up to 16.0
---------------
Table P10.2.4-3: Anchor Size vs. Tightening Torque for Standard Weight Concrete
Anchor
Size
(in)
Anchor
Tightening
Torque
(ft-lbs)
3/8
1/2
5/8
3/4
25.00
40.00
60.00
110.0
PAGE 3 of 3
SECTION – P10.2.4
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KCAB Wedge Type Anchor Selection Guide
For wedge type concrete anchors, the factor of safety is computed using the following
equation.
1 = 1/[(T/TA)(5/3) + (P/PA)(5/3)]
(Eq. P10.3.1-1)
Where:
F.S. = the factor of safety.
T = the applied tensile force acting on the anchor (lbs).
TA = the allowable tensile load for the specified anchor size (lbs).
P = the applied shear force acting on the anchor (lbs).
PA = the allowable shear load for the specified anchor size (lbs).
It is possible to use Equation P10.3.1-1 to compute an allowable combined anchor load
where the applied tensile force is equal to the applied shear force. With this information, a
capacity envelope may be constructed for the various wedge type concrete anchors that
are specified and used by Kinetics Noise Control. In Equation P10.3.1-2 the applied
tensile load has been made equal to the applied shear load, and is designated as FC.
1 = 1/[(FC/TA)(5/3) + (FC/PA)(5/3)]
(Eq. P10.3.1-2)
Solving Equation P10.3.1-2 for FC and simplifying will yield the following result.
FC = ( TA * PA) * [1/(TA(5/3) + PA(5/3))](3/5)
(Eq. P10.3.1-3)
F.S.
The data provided in Table P10.3.1-1 is based on concrete with a minimum compressive
strength of 3,000 psi and a minimum embedment depth equal to 8 anchor diameters. The
capacity envelopes for the anchors presented in Table P10.3.1-1 are plotted in Figures
P10.3.1-1 through P10.3.1-4.
KCAB ANCHOR SELECTION GUIDE
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P10.3.1
MEMBER
ASD
ASD
ASD
LRFD
LRFD
Minimum
Allow. Allow.
Allow.
Allow. Allow.
Anchor Required
Tensile Shear
Comb.
Tensile Shear
Size2
Embed.
Load1
Load1 Load1
Load1 Load1
Depth
(in)
(T=0)
(P=0) (FC=T=P) (T=0)
(P=0)
(in)
(lbs)
(lbs)
(lbs)
(lbs)
(lbs
LRFD
Allow.
Com.
Load1
(FC=T=P)
(lbs)
1/4
2
280
400
215
392
560
301
3/8
3
588
1,018
480
823
1,425
672
1/2
4
874
1,769
744
1,224
2,477
1,041
5/8
5
1,317
2,640
1,118
1,844
3,696
1,565
3/4
6
1,668
4,225
1,486
2,335
5,915
2,080
7/8
7
2,264
6,210
2,044
3,170
8,694
2,861
1
8
2,535
8,328
2,346
3,549
11,659
3,285
1
9
2,730
8,328
2,503
3,822
11,659
3,504
1-1/4
10
5,105
9,918
4,301
7,147
13,885
6,021
1) For Non-California projects these values may be inflated by 33-1/3% for seismic and wind
applications. For California Non-OSHPD projects these values must be reduced by 20%. For
California OSHPD projects the allowable loads for lightweight, 2,000 psi, concrete must be
reduced by 20% to simulate cracked concrete. In this case the values listed here do not apply.
the clearance space with grout or epoxy, or use the appropriate Kinetics Noise Control model TG
Grommet.
Table P10.3.1-1; KCAB Wedge Type Anchor Basic Capacities.
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P10.3.1
MEMBER
900
1/4" Anchor
700
3/8" Anchor
600
1/2" Anchor
500
400
300
Anchor Tensile Load (lbs)
800
200
100
0
0
200
400
600
800
1,000
1,200
1,400
1,600
1,800
Anchor Shear Load (lbs)
Figure P10.3.1-1; Basic ASD Values for 1/4 through 1/2 Anchors.
2,500
5/8" Anchor
2,000
3/4" Anchor
7/8" Anchor
1,500
1,000
500
0
0
1,000
2,000
3,000
4,000
5,000
6,000
7,000
Figure 10.3.1-2; Basic ASD Values for 5/8 Though 7/8 Anchors
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P10.3.1
MEMBER
6,000
5,000
1" Anchor @ 9" Embed.
1-1/4" Anchor
4,000
3,000
2,000
1,000
0
0
2,000
4,000
6,000
8,000
10,000
Figure P10.3.1-3; Basic ASD Values for 1 through 1-1/4 Anchors.
1,400
1,200
1/4" Anchor
3/8" Anchor
1,000
1/2" Anchor
800
600
400
200
0
0
250
500
750
1,000 1,250 1,500 1,750 2,000 2,250 2,500
Figure 10.3.1-4; Basic LRFD Values for 1/4 Though 5/8 Anchors
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P10.3.1
MEMBER
3,000
5/8" Anchor
3/4" Anchor
2,500
7/8" Anchor
2,000
1,500
3,500
1,000
500
0
0
1,000
2,000
3,000
4,000
5,000
6,000
7,000
8,000
9,000
Figure P10.3.1-5; Basic LRFD Values for 5/8 through 7/8 Anchors.
8,000
7,000
1" Anchor @8" Embed.
6,000
1-1/4" Anchor
5,000
4,000
3,000
2,000
1,000
0
0
2,000
4,000
6,000
8,000
10,000
12,000
14,000
Figure 10.3.1-2; Basic LRFD Values for 1 Though 1-1/4 Anchors
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P10.3.1
MEMBER
KUAB Type P Undercut Seismic Anchor Selection Guide
T = the applied tensile load in the anchor.
TA = the allowable tensile load in the anchor, ASD or LRFD.
P = the applied shear load in the anchor.
PA = the allowable shear load in the anchor, ASD or LRFD.
FC = the combined load case where T = P.
For applied shear loads P 0.2PA the full allowable load in tension TA may be taken. For
applied tensile loads T 0.2TA the full allowable load in shear PA may be taken. For all
other conditions;
(T/TA) + (P/PA)
1.2
(Eq. P10.3.2-1)
Setting T = P = FC, and solving for the combined load FC will provide the closing data point
for the Seismic Restraint Envelopes.
FC = 1.2TAPA/(PA+TA)
(Eq. P10.3.2-2)
The ASD, and LRFD Allowable Tensile, Shear, Combined Loads for the Kinetics Noise
Control model KUAB Type P Undercut Seismic Anchors are given in Table P10.3.2-1.
The Seismic Restraint Envelopes for those anchors are presented in Figures P10.3.2-1
and P10.3.2-2 for ASD values, and Figures P10.3.2-3 and P10.3.2-4 for LRFD values.
The Kinetics Noise Control model KUAB Type P Undercut Seismic Anchors are
purchased from HILTI, Inc., and are described in Document P.10.2.2. The Seismic
Restraint Envelopes for this type of anchor will be constructed according to the
information found in ICC ES Report number ESR-1546, Section 4.2.1. In this document,
the following definitions will apply.
KUAB TYPE P SEISMIC ANCHOR SELECTION GUIDE
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P10.3.2
MEMBER
Table P10.3.2-1; KUAB Type P Undercut Seismic Type Anchor Capacities
Anchor
Size1
(mm)
[
ASD
ASD
ASD
LRFD
Min.
Allow. Allow.
Allow.
Allow.
Req.’d
Tensile Shear
Comb.
Tensile
Embed.
Load2
Load2 Load2
Load2
Depth
(T=0)
(P=0) (FC=T=P) (T=0)
(in)
(lbs)
(lbs)
(lbs)
(lbs)
Stud ]
(in)
LRFD
Allow.
Shear
Load2
(P=0)
(lbs)
LRFD
Allow.
Comb.
Load2
(FC=T=P)
(lbs)
M10 [ 3/8 ]
4
4,365
1,993
1,642
6,111
2,790
2,299
M12 [ 1/2 ]
5
5,457
2,889
2,267
7,640
4,045
3,174
M16 [ 5/8 ]
7-1/2
10,914
5,380
4,324
15,280
7,532
6,054
M20 [ 3/4 ]
9-7/8
16,371
8,269
6,593
22,919
11,577
9,230
the clearance space with grout or epoxy, or use the appropriate Kinetics Noise Control
model TG Grommet.
2) These values may not be inflated by 33-1/3% for seismic and wind applications!
3,500
3,000
M10 Anchor
2,500
M12 Anchor
2,000
1,500
1,000
(HILTI HDA-P Undercut Concrete Anchors)
500
0
0
1,000
2,000
3,000
4,000
5,000
6,000
Figure P10.3.2-1; Basic ASD Values for M10 and M12 Anchors.
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P10.3.2
MEMBER
9,000
7,000
M16 Anchor
6,000
M20 Anchor
5,000
4,000
3,000
8,000
2,000
1,000
0
0
5,000
10,000
15,000
20,000
Figure P10.3.2-2; Basic ASD Values for M16 and M20 Anchors.
4,500
4,000
3,500
M10 Anchor
3,000
M12 Anchor
2,500
2,000
1,500
1,000
500
0
0
2,000
4,000
6,000
8,000
10,000
Figure P10.3.2-3; Basic LRFD Values for M10 and M12 Anchors.
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P10.3.2
MEMBER
12,000
M16 Anchor
10,000
M20 Anchor
8,000
6,000
14,000
4,000
2,000
0
0
5,000
10,000
15,000
20,000
25,000
Figure P10.3.2-4; Basic LRFD Values for M16 and M20 Anchors.
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P10.3.2
MEMBER
ANCHOR INSTALLATION INSTRUCTION KCAB-KCCAB
KCAB and KCCAB anchors shall be installed in holes drilled into the base material using carbidetipped masonry drill bits complying with ANSI B212.15-1994. The nominal drill bit diameter shall
be equal to that of the anchor. The drilled hole shall exceed the required anchor embedment
depth by at least one anchor diameter to permit over-driving of anchors and to provide a dust
collection area.
Anchors shall be installed to a minimum embedment depth and with at least the minimum edge
distance as specified in the table below.
Anchor Size
0.25
0.38
0.50
0.62
0.75
1.00
1.00 (Hi Capacity)
KCAB Data
Minimum Edge
Minimum
Distance (in)
Embedment
(in)
2.0
3.38
3.0
4.88
4.0
6.75
5.0
8.25
6.0
9.75
8.0
13.50
9.0
13.50
KCCAB Data
Minimum
Minimum
Edge Distance
Embedment
(in)
(in)
2.00
3.25
4.00
4.75
6.50
7.50
8.75
9.00
The anchor shall be hammered into the predrilled hole until at least 6 threads (KCAB) or 4 threads
(KCCAB) are below the fixture surface. The nut shall be tightened against the washer until the
torque values specified in the table below are obtained.
Anchor Size
0.25
0.38
0.50
0.62
0.75
1.00
KCAB Data
Torque (in lb)
Torque (Nm)
4
6
20
27
40
54
85
115
150
202
325
439
KCCAB Data
Torque (in lb)
Torque (Nm)
25
40
60
110
34
54
81
149
See page to follow for detailed installation procedure.
TITLE: KCAB & KCCAB ANCHOR INSTALLATION INSTRUCTIONS
PAGE 1 of 2
SECTION – P10.4
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1) Hammer drill a hole to the same nominal diameter as the KCAB or KCCAB using a bit
complying with ANSI B212.15-1994. The hole depth should exceed the listed embedment
depth by 1 anchor diameter. The component being restrained can be used as a guide to
properly locate the hole.
2) Clean the hole using an air source to blow the debris out.
3) Drive the anchor bolt into the hole using a hammer.
a) KCAB anchors should be driven in to their rated embedment depth (with at least 6
threads being driven below the surface against which the nut will bear).
b) KCCAB anchors should be driven in to their rated embedment depth (with the marker
on the side of the anchor flush with the concrete surface and with at least 4 threads
being driven below the surface against which the nut will bear).
4) Tighten the nut to the recommended installation torque.
TITLE: KCAB & KCCAB ANCHOR INSTALLATION INSTRUCTIONS
PAGE 2 of 2
SECTION – P10.4
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KINETICS SEISMIC INSTALLATION INSPECTION
Piping/Ductwork Deviation
Project:
Pipe/Duct Size:
Cable Restrained Ductwork/Piping
Inspection Date:
Performed By:
P.O. Number:
Ref No:
1) What is the basic concern in the restraint at this location
o
Comment
3) Is the restraint connection to the equipment consistent with that modeled in the analysis?
o Yes, o Comment
4) Is the restraint connection to the structure consistent with that modeled in the analysis?
o Yes, o Comment
5) Is the mounting hole diameter 1/8” or less greater than the attachment hardware diameter or is
it grouted to prevent lateral motion between the equipment, restraint component and
structure?
o Yes, o Comment
If Anchored to Concrete
Anchor Type and Manufacturer
o As specified in calculation, o Other
Is Embedment Consistent with analysis?
o Yes, o Comment
How was Embedment Determined?
If attached to beam or truss
Is connection secure and such that the beam or truss is not subjected to undesirable strain?
o Yes,
o Comment
6) Is the Support strength adequate for the seismic load?
o Yes – Based on
o Not Determined – Must be verified by Equipment manufacturer
Comments
7) Is the localized building structure adequate for the seismic load?
o Yes – Based on
o Not Determined – Must be verified by the building structural engineer
Comments
2) What is the observed Cable size and is it adequate? o Yes,
8) Based on the above, recommendations to ensure that the equipment is restrained adequately
to meet specified code requirements?
o Yes, o No, o Not Determined, o Yes
with conditions
This inspection is applies to the connection between the restrained equipment and the structure only. Kinetics bears no responsibility for the ability of either of these components
to resist the seismic load or remain operational after the seismic event. This inspection is subject to all items identified on the standard disclaimer that are not otherwise
addressed explicitly by this inspection. No other warranty, expressed or implied, is made or intended. 7/05/2002
KINETICS SEISMIC INSTALLATION INSPECTION (PIPE/DUCT/CONDUIT)
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A1.1
MEMBER
GENERAL PIPING/DUCTWORK INSTALLATION
REQUIREMENTS (IBC APPLICATIONS)
1) Unless otherwise noted, it is assumed that all piping or ductwork falls into the “Medium
Deformability” or better category. All restraints are sized based on “Medium
Deformability” criteria. Additional restraint requirements may be necessary for
“Low Deformability” systems. “Low Deformability” is defined as systems that will
fail if deformed by a factor of 1.5 times the point at which the a permanent set begins
to occur. Items such as glass lined piping or systems that are made of, or interface
with components that are brittle in nature.
2) It is normally unknown whether or not piping/ductwork mounted within 12” of the
structure, is considered to be “Highly Deformable”, is fitted with non-moment
generating connections and/or is free to swing without contacting structure, other
piping, ductwork or equipment. (Refer also to the 12” rule in the Kinetics Seismic
Design Manual section D7.4.1 (piping) and D8.4.1 (Ductwork) and non-moment
generating connections as defined in section D7.5.5 (piping) or D8.5.5 (Ductwork)).
As a result, all piping is assumed not to conform to the above and where the size is
such that restraint may be required, it is so indicated on the drawings. In these areas,
if all of the above qualifications can be met for the full length of a run, restraints
can be omitted on that run. (Note: “High Deformability” systems are those which will
not catastrophically fail, even if deformed by a factor of 3.5 times the point at which a
permanent set begins to occur. Items like brazed tubing, welded steel piping, piping
using threaded forged steel fittings or flanges and glued PVC piping typically fall into
this category.)
3) Small ducts are not shown as requiring restraint, subject to item 4 below and in
accordance with SMACNA as permitted by Section 1621.3.9 in the IBC, even if the
importance factor for these systems is 1.5.
Because much of the detailed information required to make final decisions on the need for
restraint on particular runs of piping or ductwork cannot be fully ascertained from the
drawings provided, the drawings or marked prints provided by Kinetics are subject to the
following:
4) Some pipe and duct sizes can often be excluded based on size. These are shown as
not restrained on the drawings provided by Kinetics. They do not require non-moment
generating connections. However, in order for the exclusion to apply, there is a further
requirement that these systems are sufficiently far away from other systems, structure,
and/or equipment; that the motion likely to result from an earthquake will not result in
contact between local components. If this is not the case, these systems will require
restraint in the same manner as the larger systems.
GENERAL PIPE/DUCT INSTALLATION REQUIREMENTS
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A1.1.1
MEMBER
6) All restraint locations shown are approximate. The maximum allowed spacing
cannot exceed the limits indicated on the supporting calculation document or
comments provided on the marked drawing itself. Restraints located at corners or
changes of direction in the pipe or duct system are assumed to be effective for both of
the adjacent runs. (This means that they are intended to be located within 24” of the
direction change centerline.)
7) No attempt has been made to ensure that adequate capacity exists in the structure to
resist the forces generated by the restrained system. Exact design forces can be
determined by prorating the provided analysis documents to the situation at hand. It is
the responsibility of the Project Structural Engineer or Engineer of Record to
indicate potential suitable restraint locations that will handle these forces in the
proximity of the locations indicated by Kinetics.
8) Restraint locations are indicated on the drawings using double ended arrows as shown
below. Arrows oriented with the axis of the pipe or duct indicate axial or longitudinal
restraints. Arrows oriented at right angles to the axis of the pipe or duct indicate lateral
or transverse restraints. Symbols showing arrow oriented both ways indicate both
lateral and axial restraint.
5) Where piping or ductwork is shown grouped and running together, it is assumed
that these are on a common trapeze and restraints will be selected and sized
accordingly. If a sufficient quantity of smaller piping, conduit or duct is mounted on a
single trapeze, the total operating weight of these components will be compared to the
minimum size exemption to determine whether or not restraint will be indicated. Thus
if 4 pieces of 1-1/2” pipe are trapezed together, their total weight exceeds that of a
single 2” pipe (the exempted limit in some cases) and restraint wil be indicated based
on their combined weight.
GENERAL PIPE/DUCT INSTALLATION REQUIREMENTS
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A1.1.1
MEMBER
Equipment Installation Inspection
Project:
P.O. Number:
Equip Type:
Tag:
Floor Mounted, Isolated or Hard Mounted
Inspection Date:
Performed By:
1) Is the Equipment arrangement consistent with that modeled in the analysis? (Attach Copy)
o Yes, o Comment
o Yes, o Comment
o Yes, o Comment
structure?
o Yes, o Comment
o Yes, o Comment
Is the concrete contiguous over the full length of the anchor?
o Yes,
o Comment
6) Is the equipment strength adequate for the seismic load?
o Yes – Based on
Comments
o Yes – Based on
Comments
2) Are the attachment clips sizes and locations consistent with that modeled in the analysis?
o Yes, o Comment
with conditions
KINETICS SEISMIC INSTALLATION INSPECTION (FLR MTD EQUIPMENT)
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A1.2
MEMBER
Cable Restrained, Isolated or Hard Mounted
Project:
P.O. Number:
Inspection Date:
Equip Type:
Tag:
Performed By:
1) Is the Equipment arrangement consistent with that modeled in the analysis? (Attach Copy)
o Yes, o Comment
o Yes, o Comment
o Yes, o Comment
structure?
o Yes, o Comment
o Yes, o Comment
Is the concrete contiguous over the full length of the anchor?
o Yes,
o Comment
6) Is the equipment strength adequate for the seismic load?
o Yes – Based on
Comments
o Yes – Based on
Comments
2) Is the cable size and location consistent with that modeled in the analysis? o Yes,
o Comment
with conditions
KINETICS SEISMIC INSTALLATION INSP (CABLE RESTRAINED EQUIPMENT)
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A1.3
MEMBER
KINETICS SEISMIC INSTALLATION CERTIFICATION
Curb Mounted Isolated or Non Isolated Equipment
Project: ____________________________ P.O. Number: _________________Inspection Date:________________
Equip Type: _________________________ Tag: _________________________Performed By: ________________
1) Is the equipment arrangement consistent with that modeled in the analysis (Attach Copy)?
o Yes, o Comment _________________________________________________________________
_____________________________________________________________________________________________
4) Is the restraint connection to the equipment consistent with that modeled in the analysis? (This may be direct to
structure for hard mounted equipment but will be direct to the equipment rail if the equipment is isolated.)
o Yes, o Comment _________________________________________________________________
____________________________________________________________________________
o As specified in calculation, o Other ____________________________________________________________
Does the min Edge Distance Exceeds the Minimum listed in the KNC Seismic manual section P10.2.1?
o Yes, o Comment __________________________________________________________________
o Yes, o Comment _________________________________________________________________
How was Embedment Determined? _____________________________________________________________
Is concrete contiguous over full length of anchor?
o Yes, o Comment _________________________________________________________________
5) Does the equipment strength appear adequate to resist the seismic load?
o Yes Based on _____________________________________________________________________
o Not Determined Must be verified by Equipment manufacturer
Comments ____________________________________________________________________________
o Yes Based on _____________________________________________________________________
o Not Determined Must be verified by the building structural engineer
Comments ____________________________________________________________________________
KINETICS
_____________________________________________________________________________________________
3) Is the connection between the curb and the structure consistent with that modeled in the analysis and in the KNC
Seismic manual section D6.2.4 as appropriate? (Note weld size, screw size and quantity, blocking etc, depending
on curb type).
o Yes, o Comment _________________________________________________________________
Seismic Design Manual
___________________________________________________________________________________________
2) If Isolated, are the internal restraint components consistent in quantity and location with that modeled in the analysis?
o Yes, o Comment _________________________________________________________________
7) Based on the above, is the equipment restrained adequately to meet specified code
requirements?
o Yes, o No, o Not Determined, o Yes with conditions
___________________________________________________________________________________________
___________________________________________________________________________________________
___________________________________________________________________________________________
___________________________________________________________________________________________
KINETICS SEISMIC INSTALLATION INSP (CURB MOUNTED EQUIPMENT)
PAGE 1 OF 1
DUBLIN, OHIO, USA MISSISSAUGA, ONTARIO, CANADA
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A1.4
MEMBER
The following section identifies those procedures that should be followed to ensure that
Housekeeping pads used in structures located in seismically prone areas, will remain
intact and in place when exposed to a seismic event. However, no claims are made in
this document as to the ability of the structural slab underneath the housekeeping pad to
withstand the seismic loads being transmitted into it. The guide is offered solely as a
recommendation to other engineers and contractors as a tool that can aid in selecting an
appropriate housekeeping pad design. As with other elements of the structure, the
Engineer of record has the final say as to the suitability of these parameters to the project
at hand.
General
Housekeeping pads have been used for years as a device to allow isolated equipment to
be more easily kept clear of debris and to enhance both the time required for maintenance
and the appearance of mechanical rooms. As the demand for appropriate seismic
restraint has become more stringent, housekeeping pads have evolved to serve as a
structural interface that distributes localized point loads generated by attached equipment
to the more globally designed mechanical room floor structure.
It is not untypical for the anchorage embedment requirements for particular pieces of
equipment to exceed the maximum permitted embedment depth in a mechanical room
floor slab. In these cases, the housekeeping slab thickness can be selected to meet the
equipment anchor needs and then through an array of anchors that connect the
housekeeping pad to the structure, this load can be distributed to a larger quantity of
smaller anchors that are compatible with the floor slab.
Critical to this interface is the housekeeping pad thickness, the grade of concrete used,
the adequacy of the connection between the housekeeping pad and the floor slab and
appropriate reinforcement in the housekeeping pad to keep it from splitting apart. It is
equally critical to ensure that the equipment anchors can not rupture the housekeeping
pad and pull free. This is accomplished by providing an adequate edge distance between
the anchor and the perimeter of the housekeeping pad itself as well as proper spacing
between the anchors.
HOUSEKEEPING PAD DESIGN
Housekeeping Pad Thickness and Perimeter Dimensions
Before specifying a housekeeping pad, it is critical to determine the size and locations of
the anchors that are being used to attach the equipment. Kinetics Noise Control or some
other reputable source should perform an analysis, with the appropriate mounting
hardware being selected and mounting locations determined. Once anchors are selected,
the embedment depth for the anchors can be identified. This is generally 8 times the
anchor diameter, but in a few cases, could be more. Refer to the Anchor section (P10) in
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Referring also to the Anchor section (P10) of this manual, the minimum allowed edge
distance is also identified by anchor size. This is the minimum allowed distance from the
anchor centerline to the nearest edge of a housekeeping pad. Using this information
along with the previously identified anchor attachment pattern, a minimum housekeeping
pad profile can be determined.
this manual or the calculation performed to verify this dimension. As it is necessary that
anchors be embedded in a single contiguous pour, it will be necessary for the anchor to
achieve its full embedment in either the structural floor slab or the housekeeping pad.
The only exception to this is when the housekeeping pad has been poured along with the
structural slab. In addition, for most applications using KCAB anchors at least 3/4” of
cover under the anchor is required. Thus, if 6” of embedment is required for the anchor, a
minimum contiguous concrete thickness of 6-3/4” is needed to accommodate this. (Note,
if the anchor is being directly embedded into a slab on grade, the minimum cover over the
end of the anchor increases to 1-1/2”. See also the chart in Section P10.2.1 of this
manual for more information on this.)
Housekeeping Pad General Layout
Tabulated Design Data Assumptions
In using the tabulated data listed in this section, the following assumptions have been
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1) The concrete used is in the housekeeping pad is 3000 psi min, standard weight.
2) Anchorage ratings have been derated to meet current US standards for all applications
except those requiring certification from OSHPD.
3) The structural concrete used is 3000 psi min and standard weight.
4) The thickness and profile are in accordance with the sizing information listed above.
5) The housekeeping pad is attached to the structural slab using 3/8” diameter x 5” long
KCAB anchor bolts that are embedded 3” into the structural slab, protrude 2” into the
housekeeping pad and are physically connected to internal #3 rebar using KSUA clips.
(It is only possible to use larger anchors if the structural slab is greater than 4” in
thickness.)
Use of Tables
1) Divide the total Operating Equipment weight by the overall length of the housekeeping
pad to get a weight per foot value.
2) Verify that the vertical dimension from the top of the housekeeping pad to the
equipment CG is less than the 2/3 of the width of the housekeeping pad. (If this is not
the case, either the pad will have to be made wider or a custom analysis will have to
be performed by Kinetics Noise Control or other qualified source.)
3) Determine the Seismic acceleration for the equipment type and location in the
structure under review. All acceleration values are listed in the attached tables include
all factors and are expressed in stress based (ASD) units regardless of the code used.
If using the 97 UBC, the IBC or TI-809-04, the values that result from the code driven
factors are strength based (LRFD) and should be reduced by a factor of 1.4 prior to
using these tables. (Note: this has already been done if using Kinetics Noise Control
provided certification documents.) If factors are provided in the project specification
that exceed the code values, the higher values should be used as a basis for design.
4) Select the table with the appropriate design acceleration factor.
5) Reading across the top of the table, find the equipment weight per foot and the
housekeeping pad thickness previously determined
6) Read down the column until you find the housekeeping width that will allow the
equipment mounting anchors to be installed and maintain adequate edge distances.
7) The value listed in upper portion of the table is the maximum center to center distance
for anchors placed around the perimeter of the housekeeping pad.
8) The value listed in lower portion of the table is the maximum spacing between anchors
in the central area of the housekeeping pad.
9) A minimum of 4 anchors is required per pad.
10) Refer to the drawing below for reinforcement and housekeeping pad details.
11) All pad reinforcement should conform to ACI standards for minimum area and
concrete coverage.
made.
Special Applications
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For Design conditions outside of those allowed by the above Tables, consult Kinetics
Noise Control.
Sample Pad Design
Pad Thickness
Embedment required for .75” anchor is 6” (from anchor table in P10.2.1 of this manual).
Minimum cover is .75” so minimum thickness is 6.75”. Use 8” pad.
Pad Length
Minimum edge distance for .75” anchor is 9.75” (from anchor table in P10.2.1 of this
manual). Minimum pad length is 9.75” (edge distance) + 112” (spacing) + 9.75” (edge
distance) or 131.5” (call it 11 ft).
Pad Width
Using above minimum edge distance the minimum width is 9.75” (edge distance) + 48”
(spacing) + 9.75” (edge distance) or 67.5”
Weight per foot of length is 10,000/11 or 909 lb/ft.
Refering to the .5g table and the 1000 lb/ft column with an 8” thick pad, the maximum
perimeter anchor spacing for a 4-6 ft wide pad is 36”. The maximum central area anchor
spacing is 48”.
Design Tables
Seismic Acceleration (at Equipment)
Equip Wt/Ft (lb)
HouseKeeping Pad Thk (in)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
0.25 g
ASD Based Values
With the 97 UBC, IBC, or TI-809-04 code reduce the LRFD "g" value by 1.4
250
4
250
6
250
8
500
4
Maximum Anchor Spacing (in)
500 500 750 750 750 750
6
8
4
6
8
10
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
47
48
48
48
48
48
48
48
46
48
48
48
48
48
48
48
45
48
48
48
48
48
48
48
45
48
48
48
48
48
48
48
34
48
48
48
48
48
48
48
34
48
48
48
48
48
48
48
33
48
48
48
48
48
48
48
33
48
48
48
48
48
48
48
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
Conditions:
10,000 lb chiller
Seismic Acceleration .47 g (in ASD units at equipment location)
Anchorage spacing (from equipment) 112” x 48”
Anchor size (from equipment analysis) .75”
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MEMBER
Equip Wt/Ft (lb)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
Equip Wt/Ft (lb)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
Equip Wt/Ft (lb)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
0.5 g
ASD Based Values
250
4
250
6
250
8
500
4
500 500 750 750 750 750
6
8
4
6
8
10
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
31
36
36
36
36
36
36
36
30
36
36
36
36
36
36
36
30
36
36
36
36
36
36
36
29
36
36
36
36
36
36
36
21
36
36
36
36
36
36
36
21
36
36
36
36
36
36
36
20
36
36
36
36
36
36
36
20
36
36
36
36
36
36
36
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
45
48
48
48
48
48
48
48
44
48
48
48
48
48
48
48
42
48
48
48
48
48
48
48
33
48
48
48
48
48
48
48
32
48
48
48
48
48
48
48
32
48
48
48
48
48
48
48
31
48
48
48
48
48
48
48
26
45
48
48
48
48
48
48
26
44
48
48
48
48
48
48
25
42
48
48
48
48
48
48
25
41
48
48
48
48
48
48
19
33
48
48
48
48
48
48
19
32
48
48
48
48
48
48
19
32
48
48
48
48
48
48
18
31
48
48
48
48
48
48
0.75 g
ASD Based Values
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
250
4
250
6
250
8
500
4
500 500 750 750 750 750
6
8
4
6
8
10
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
36
27
36
36
36
36
36
36
36
26
36
36
36
36
36
36
36
26
36
36
36
36
36
36
36
24
36
36
36
36
36
36
36
21
36
36
36
36
36
36
36
20
36
36
36
36
36
36
36
19
36
36
36
36
36
36
36
17
35
36
36
36
36
36
36
13
27
36
36
36
36
36
36
12
26
36
36
36
36
36
36
11
26
36
36
36
36
36
36
10
25
36
36
36
36
36
36
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
48
47
48
48
48
48
48
48
48
32
48
48
48
48
48
48
48
31
48
48
48
48
48
48
48
30
47
48
48
48
48
48
48
24
40
48
48
48
48
48
48
23
38
48
48
48
48
48
48
23
37
48
48
48
48
48
48
22
35
48
48
48
48
48
48
19
32
48
48
48
48
48
48
19
31
48
48
48
48
48
48
18
30
47
48
48
48
48
48
18
29
45
48
48
48
48
48
14
24
40
48
48
48
48
48
13
23
38
48
48
48
48
48
13
23
37
47
48
48
48
48
13
22
35
45
48
48
48
48
1.00 g
ASD Based Values
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
250
4
250
6
250
8
500
4
500 500 750 750 750 750
6
8
4
6
8
10
36
36
36
36
36
36
36
36
35
36
36
36
36
36
36
36
28
36
36
36
36
36
36
36
29
36
36
36
36
36
36
36
24
36
36
36
36
36
36
36
20
36
36
36
36
36
36
36
17
32
36
36
36
36
36
36
15
29
36
36
36
36
36
36
13
27
35
36
36
36
36
36
11
25
34
36
36
36
36
36
11
23
28
29
29
30
30
30
10
21
27
29
30
30
31
31
9
19
27
29
30
31
31
32
8
18
26
29
30
31
32
33
6
13
19
19
20
20
20
20
6
12
19
19
20
20
20
20
5
11
18
19
20
20
20
21
5
10
17
19
20
20
21
21
42
48
48
48
48
48
48
48
39
48
48
48
48
48
48
48
37
48
48
48
48
48
48
48
25
42
48
48
48
48
48
48
25
39
48
48
48
48
48
48
24
37
48
48
48
48
48
48
19
32
48
48
48
48
48
48
18
30
47
48
48
48
48
48
18
29
44
48
48
48
48
48
17
28
41
48
48
48
48
48
15
25
42
48
48
48
48
48
15
25
39
48
48
48
48
48
14
24
37
47
48
48
48
48
14
23
35
43
48
48
48
48
11
19
32
42
48
48
48
48
11
18
30
39
47
48
48
48
10
18
29
37
44
48
48
48
10
17
28
35
41
45
48
48
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
PAGE 5 OF 6
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614-889-0540
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DOCUMENT:
A3.0
MEMBER
Equip Wt/Ft (lb)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
Equip Wt/Ft (lb)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
Equip Wt/Ft (lb)
Perimeter
Spacing
(in)
Central Area
(OC Spg)
(in)
Pad Wdth (ft)
1 -2
2 -4
4 -6
6 -8
8 - 10
10 - 12
12 - 15
15 - 20
1
2
4
6
8
10
12
15
-
2
4
6
8
10
12
15
20
1.50 g
ASD Based Values
250
4
250
6
250
8
500
4
500 500 750 750 750 750
6
8
4
6
8
10
24
34
36
36
36
36
36
36
19
29
36
36
36
36
36
36
14
25
36
36
36
36
36
36
12
20
23
24
25
25
25
26
10
18
22
24
25
25
26
26
8
16
21
23
24
25
26
26
7
12
16
16
17
17
17
17
6
11
15
16
17
17
17
17
5
10
14
16
16
17
17
17
9
13
16
16
17
17
17
8
11
12
12
12
13
13
7
10
11
12
12
13
13
7
9
11
12
12
12
13
6
9
10
11
12
12
12
6
6
6
6
7
7
5
6
6
6
6
7
5
6
6
6
6
7
5
6
6
6
6
6
30
47
48
48
48
48
48
48
28
42
48
48
48
48
48
48
26
38
48
48
48
48
48
48
18
30
47
48
48
48
48
48
18
28
42
48
48
48
48
48
17
26
38
45
48
48
48
48
13
23
37
47
48
48
48
48
13
21
34
42
48
48
48
48
13
21
31
38
43
47
48
48
12
20
29
35
39
42
45
47
11
18
30
39
47
48
48
48
10
18
28
36
42
47
48
48
10
17
26
33
38
42
45
48
10
16
25
31
35
38
41
44
8
13
23
30
37
42
47
48
8
13
21
28
34
38
42
47
7
13
21
26
31
35
38
42
7
12
20
25
29
32
35
38
2.00 g
ASD Based Values
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
250
4
250
6
250
8
500
4
500 500 750 750 750 750
6
8
4
6
8
10
14
22
27
29
30
31
31
32
10
19
25
27
29
30
31
31
8
16
23
26
28
29
30
31
6
11
15
15
16
16
16
16
5
9
13
15
15
16
16
16
8
12
14
15
15
16
16
6
8
9
9
9
10
10
5
8
8
9
9
9
10
5
7
8
8
9
9
9
7
8
8
9
9
9
5
6
6
6
6
6
5
5
6
6
6
6
5
5
6
6
6
5
5
6
6
6
-
-
-
-
24
37
48
48
48
48
48
48
22
33
45
48
48
48
48
48
21
30
39
44
47
48
48
48
14
24
37
47
48
48
48
48
14
22
33
40
45
48
48
48
13
21
30
36
39
42
44
47
10
18
29
37
44
48
48
48
10
17
26
33
38
42
45
48
10
16
25
30
34
37
39
42
10
15
23
28
31
33
35
37
8
14
24
31
37
42
47
48
8
14
22
28
33
37
40
44
8
13
21
26
30
33
36
39
8
13
20
24
28
30
32
34
6
10
18
24
29
33
37
42
6
10
17
22
26
30
33
37
6
10
16
21
25
28
30
33
6
10
15
20
23
25
28
30
2.50 g
ASD Based Values
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
250
4
250
6
250
8
500
4
500 500 750 750 750 750
6
8
4
6
8
10
9
16
20
21
22
22
23
23
7
13
18
20
21
21
22
22
5
10
17
19
20
21
21
22
7
9
10
10
11
11
11
6
8
9
10
10
10
11
5
7
9
9
10
10
10
5
5
6
6
6
6
5
5
5
6
6
5
5
5
6
5
5
5
-
-
-
-
-
-
-
-
20
31
45
48
48
48
48
48
18
28
38
43
47
48
48
48
17
25
33
37
39
41
42
43
12
20
31
39
45
48
48
48
11
18
28
34
38
41
43
46
11
17
25
30
33
35
37
39
9
15
24
31
36
41
45
48
8
14
22
28
32
35
38
41
8
13
20
25
28
31
33
35
8
13
19
23
26
28
29
31
7
12
20
26
31
35
39
43
7
11
18
24
28
31
34
37
7
11
17
22
25
28
30
32
7
11
16
20
23
25
27
29
5
9
15
20
24
28
31
35
5
8
14
18
22
25
28
31
8
13
17
20
23
25
28
8
13
16
19
21
23
25
1000 1000 1000 1000 1500 1500 1500 1500
4
6
8
10
4
6
8
10
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A3.0
MEMBER
Restraint Element Deflection Limits
When testing any type of mechanical or structural component, it is necessary to have an
adequate definition of failure, and measurable quantity that will allow the point of failure to
be accurately determined. The first definition of failure is breakage or fracture of the
component. If the component does not break, the failure criterion is usually linked to the
yield point of the material of the component. The typically listed yield point of a ferrous
material is the 0.2% Offset Yield Point. This is the stress level that corresponds to a
permanent strain of 0.002 in/in.
The purpose of this document is to provide a set of guidelines for predicting the deflection
of a component at the 0.2% Offset Yield Point for various generic component types.
Axially Loaded Components:
Figure A6.1.1-1 shows a typical axially loaded component. The component may be either
loaded in tension, or compression. The discussion which follows will apply to both tension
and compression. If the component is long and slender, and loaded in compression, care
must be taken to ensure that the primary failure mode is not in buckling.
F
F
L
L
F
Introduction:
F
Figure A6.1.1-1: Axially Loaded Components.
For ferrous and other linear elastic materials, the following basic equations will apply.
A
=E*
(Eq. A6.1.1-1)
RESTRAINT ELEMENT DEFLECTION LIMITS
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A6.1.1
MEMBER
Where:
E = the elastic modulus of component material, also known as Young’s Modulus.
= the strain in the component.
A = the axial stress in the component.
The strain acting in the component, , is defined as the change in the length, L, of the
component under the action of the force F divided by the unloaded length, L, of the
component, or:
(Eq. A6.1.1-2)
Rearrange Equation A6.1.1-1 to solve for .
=
A
/E
(Eq. A6.1.1-3)
Set Equation A6.1.1-2 equal to Equation A6.1.1-3, and solve for L.
L=L*
A
/E
(Eq. A6.1.1-4)
Let A be equal to the 0.2% Offset Yield Point stress,
component at the 0.2% Offset Yield Point is:
L=L*
YP
YP.
Then, the deflection for the
/E
(Eq. A6.1.1-5)
Table A6.1.1-1 presents the measurable value of L for various values of L.
Table A6.1.1:
L vs. L for Axially Loaded Components.
At a 0.2% Offset Yield Point
Component
Length
L
(in)
Length
Change
L
(in)
Component
Length
L
(in)
Length
Change
L
(in)
Component
Length
L
(in)
Length
Change
L
(in)
1.0
2.0
4.0
6.0
8.0
10.0
12.0
14.0
0.0020
0.0040
0.0080
0.0120
0.0160
0.0200
0.0240
0.0280
16.0
18.0
24.0
30.0
36.0
42.0
48.0
54.0
0.0320
0.0360
0.0480
0.0600
0.0720
0.0840
0.0960
0.1080
60.0
72.0
84.0
96.0
108.0
120.0
132.0
148.0
0.1200
0.1440
0.1680
0.1920
0.2160
0.2400
0.2640
0.2960
= L/L
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A6.1.1
MEMBER
Cantilever Component with an End Load:
Figure A6.1.1-2 shows an end loaded cantilever component.
F
Figure A6.1.1-2: Cantilever Component with an End Load.
Because its impact is insignificant and for the sake of simplicity, the shear stress in the
component will be ignored. The maximum deflection for a cantilever beam with an end
load occurs at the load point and is found in many standard references as:
YM = F * L3 / (3 * E * I )
(Eq. A6.1.1-6)
Where:
F = the load applied at the end of the cantilever component.
I = the area moment of inertia of the component parallel to the load.
L = the length of the component.
YM = the maximum deflection at the end of the cantilever component.
L
In general the bending stress in any beam type component is given by:
B
=M*c/I
(Eq. A6.1.1-7)
Where:
c = the distance from the neutral axis to the outer fibers of the component.
M = the bending moment in the component at the support.
B = the bending stress in the component at the support.
The bending moment at the support will be as follows.
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A6.1.1
MEMBER
M=F*L
(Eq. A6.1.1-8)
Let YP be equal to B and solve for F. This will be the force required to yield the
component at the support.
F=
YP
*I/(L*c)
(Eq. A6.1.1-9)
Substitute Equation A6.1.1-9 into Equation A6.1.1-6 to yield the following result.
/ E)
YP
(Eq. A6.1.1-10)
The result in Equation A6.1.1-10 will be more useful if it is expressed in a dimensionless
form as shown below.
(YM / L) = (1/3) * (L / c) *(
YP
/ E)
(Eq. A6.1.1-11)
Table A6.1.1-2 gives the results of Equation A6.1.1-11.
Table A6.1.1-2: (YM / L) vs. (L / c) For a Cantilever Component.
L/c
YM / L
L/c
YM / L
L/c
YM / L
1.0
2.0
4.0
6.0
8.0
10.0
0.00067
0.00133
0.00267
0.00400
0.00533
0.00667
20.0
30.0
40.0
50.0
60.0
70.0
0.01333
0.02000
0.02667
0.03333
0.04000
0.04667
80.0
90.0
100.0
150.0
200.0
250.0
0.05333
0.06000
0.06667
0.10000
0.13333
0.16667
YM = (1/3) * (L2 / c) *(
Simply Supported Component with a Center Load:
Figure A6.1.1-3 shows a simply supported component with a center load. As it is
insignificant and for simplicity’s sake, the shear stress in the component will be ignored.
The maximum deflection for a simply supported beam with a center load occurs at the
load point and is found in many standard references as:
YM = F * L3 / (48 * E * I )
(Eq. A6.1.1-12)
The maximum bending moment occurs at the center of the beam, and is given by:
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A6.1.1
MEMBER
M=F*L/4
(Eq. A6.1.1-13)
F
L
Figure A6.1.1-3: Simply Supported Component with a Center Load.
Following the same procedure as with the cantilever component, we may obtain the
following results.
YM = (1/12) * (L2 / c) *(
YP
/ E)
(Eq. A6.1.1-14)
(YM / L) = (1/12) * (L / c) *(
YP
/ E)
(Eq. A6.1.1-15)
Table A6.1.1-3: (YM / L) vs. (L / c) For a Simply Supported Component.
L/c
YM / L
L/c
YM / L
L/c
YM / L
1.0
2.0
4.0
6.0
8.0
10.0
0.00017
0.00033
0.00067
0.00100
0.00133
0.00167
20.0
30.0
40.0
50.0
60.0
70.0
0.00333
0.00500
0.00667
0.00833
0.01000
0.01167
80.0
90.0
100.0
150.0
200.0
250.0
0.01333
0.01500
0.01667
0.02500
0.03333
0.04167
L/2
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A6.1.1
MEMBER
Component with Fixed Supports and a Center Load:
Figure A6.1.1-4 shows a component with fixed ends and a center load. Due to its minimal
impact and to simply the analysis, the shear stress in the component will be ignored.
F
L
Figure A6.1.1-4: Component with Fixed Ends and a Center Load.
The maximum deflection for a beam with fixed ends and a center load, again, occurs at
the load point and is found in many standard references as:
YM = F * L3 / (192 * E * I )
(Eq. A6.1.1-16)
The maximum bending moment occurs at the center of the beam, and is given by:
M=F*L/8
(Eq. A6.1.1-17)
Following the same procedure as with the simply supported component, we may obtain
the following results.
YM = (1/24) * (L2 / c) *(
YP
/ E)
(Eq. A6.1.1-18)
L/2
(YM / L) = (1/24) * (L / c) *(
YP
/ E)
(Eq. A6.1.1-19)
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A6.1.1
MEMBER
Table A6.1.1-4: (YM / L) vs. (L / c) For a Component with Fixed Supports
L/c
YM / L
L/c
YM / L
L/c
YM / L
1.0
2.0
4.0
6.0
8.0
10.0
0.000083
0.000167
0.000333
0.000500
0.000667
0.000833
20.0
30.0
40.0
50.0
60.0
70.0
0.00167
0.00250
0.00333
0.00417
0.00500
0.00583
80.0
90.0
100.0
150.0
200.0
250.0
0.00667
0.00750
0.00833
0.01250
0.01667
0.02083
Summary of Results:
For the axially loaded components, Equation A6.1.1-5 may be written for a 0.2% Offset
Yield Point as follows.
L / L = 0.002
(Eq. A6.1.1-20)
For the components that may be modeled as some type of beam element in bending, the
results in Tables A6.1.1-2 through A6.1.1-4 may be best summarized, and be more useful
in the graphical form as shown in Figure A6.1.1-5.
Equation A6.1.1-20 and Figure A6.1.1-5 will allow an investigator to predict the deflection
of a component at failure as defined by the 0.2% Offset Yield Stress. If significant plastic
deformation is to be permitted, then this deflection will allow the investigator to predict the
deflection at which plastic deformation has truly begun.
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A6.1.1
MEMBER
Figure A6.1.1-5: YM /L vs. L/c at a 0.2% Offset Yield Point
For Beam Type Components
0.070
0.065
0.060
Cantilever Support
0.055
Simple Supports
0.050
Fixed Supports
0.045
0.040
YM /L 0.035
0.030
0.025
0.020
0.015
0.010
0.005
0.000
0
10
20
30
40
50
60
70
80
90
100
L/c
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A6.1.1
MEMBER
Seismic Design Data for Lag Screws
Lag screws are used for connections and attachments to wooden structures. Care must
be taken when using Lag Screws for critical installations because the effective strength of
the connection will depend on the type, grade, and condition of the wood used in the
structure to which the connection is being made. This document will assume that the
wood is an Eastern Soft Woods (Spruce-Pine-Fir(s)), Western Cedars, or Western
Woods with a Specific Gravity of 0.36. The tabulated values of allowable shear load, ZS,
will be based on single shear with the load being perpendicular to the grain of the wood,
and on the use of a 1/4 thick side plate. This will produce the most conservative
allowable values.
Lag Screw Basic Data:
A typical Hex Head Lag Screw is shown in Figure A7.3-1. The basic information is
tabulated in Table A7.3-1.
F
ØD
H
P
L
Figure A7.3-1; Typical Hex Head Lag Screw.
Table A7.3-1; Hex Head Lag Screw Dimensional Data.
Lag Screw
Size
D
(in)
Width
Across Flats
F
(in)
Head Height
H
(in)
Point Length
P
(in)
1/4
3/8
0.172
0.217
5/16
1/2
0.219
0.271
3/8
9/16
0.250
0.325
1/2
3/4
0.344
0.433
5/8
15/16
0.422
0.541
3/4
1-1/8
0.500
0.650
Introduction:
SEISMIC DESIGN DATA FOR LAG SCREWS
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A7.3
MEMBER
Lag Screw Installation Data:
S
E1
E2
T
ØD
E3
L
Ød
Figure A7.3-2; Typical Lag Screw Installation Guide.
The Basic Rules & Data for installing Lag Screws are illustrated in Figure A7.3-2 and
Table A7.3-2. Do not install Lag Screws in the End Grain of a piece of wood for
seismic applications!
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A7.3
MEMBER
Table A7.3-2; Lag Screw Installation Data.
1/4
5/16
3/8
1/2
5/8
3/4
1.00
1.25
1.50
2.00
2.50
3.00
1.00
1.25
1.50
2.00
2.50
3.00
0.375
0.469
0.563
0.75
0.938
1.125
2.00
2.50
3.00
4.00
5.00
6.00
0.250
2.50
0.375
3.00
0.500
3.00
0.125
3.00
0.250
3.50
0.375
3.50
0.500
3.50
0.125
3.50
0.250
4.00
0.375
4.00
0.500
4.00
0.125
5.00
0.250
5.00
0.375
5.00
0.500
5.00
0.125
6.00
0.250
6.00
0.375
6.00
0.500
7.00
0.125
7.00
0.250
7.00
0.375
8.00
0.500
8.00
1/8
5/32
9/32
13/64
3/16
1/4
15/64
21/64
19/64
13/32
23/64
31/64
Hard
Soft
Mtg.
Min. Min.
Embed.
Lag
Min.
Screw Wood Wood
Plate
End Edge
Length Pilot
Size Spacing
Depth
Pilot
Thick.
Dist. Dist.
Drill
Drill
E3
D
S
L
E2
E1
T
(in)
(in)
(in)
(in)
d
d
(in)
(in)
(in)
(in)
(in)
0.125
2.50
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A7.3
MEMBER
Lag Screw Allowable Load Data:
The Basic Allowable Load Data for Lag Screws with an embedment equal to eight (8)
times the basic diameter, not including the point, are given in Figure A7.3-3 and Table
A7.3-3. The basic allowable loads have been increased by a Duration Factor of 1.6 for
seismic and wind loading. For an embedment of less than eight (8) times the basic
diameter, the values in Table A7.3-3 may be multiplied by the ratio of the actual
embedment divided by eight (8) times the basic diameter.
ZT
ZA
A°
T
ZS
ØD
E3=8D
L
P
Figure A7.3-3; Typical Lag Screw in Combined Tension and Shear.
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A7.3
MEMBER
Table A7.3-3; Lag Screw Allowable Load Data.
1/4
5/16
3/8
1/2
5/8
3/4
2.00
2.50
3.00
4.00
5.00
6.00
Allowable
Allowable Allowable
Load
Tensile
Shear
Combined
Angle
Load
Load
Load
A
ZT
ZS
ZA
(deg)
(lbs)
(lbs)
(lbs)
438
652
893
1,478
2,184
3,005
272
368
432
624
880
1,168
0
272
30
301
45
336
60
380
0
368
30
413
45
470
60
547
0
432
30
496
45
582
60
705
0
624
30
729
45
878
60
1,101
0
880
30
1,034
45
1,255
60
1,594
0
1,168
30
1,379
45
1,682
60
2,157
Lag Embedment
Size
Depth
D
8D
(in)
(in)
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A7.3
MEMBER
KHRC-A Rod Stiffener Data for 0°
A
30°
This document will aid the designer in determining if hanger rod reinforcement, rod
stiffeners, will be required for a given application. If they are required, recommendations
for a minimum stiffener size will be made. Also, rod stiffener clamp locations and spacing
will be made based on the use of Kinetics Noise Control model KHRC-A Adjustable
Angle Stiffener Kit. This kit is a single clamp system that is shown in Figure A8.1.1-1. One
kit will be required for each clamp location. A minimum of two clamp kits will be required
for each hanger rod stiffener. The clamps and rod stiffener are assembled to the hanger
rod as shown in Figure A8.1.1-2. The dimensions shown as L1, L2, and L3 are the
maximum allowable installation dimensions for locating and spacing the KHRC-A clamp
kits.
Buckling Analysis:
Buckling failure is a catastrophic form of failure that occurs at stresses that are much
lower that those required to yield the material. It is more of a function of the geometry of
the components than it is a function of the material. In general it is very difficult to predict
the onset of buckling. Thus, the approach used in this document will of necessity be very
conservative. All of the basic assumptions described below will lead to a conservative
result.
There are many theories that address buckling In general there are long, intermediate,
and short columns. For long columns, Euler’
s formula is most often used with good
results. For intermediate and short columns, there are many different approaches that
would result in many iterative calculations for each case to be investigated. In order to
provide reliable results with reasonable time expenditures, Euler’
s formula was used was
used to determine the maximum un-reinforced hanger rod length. The hanger rods were
modeled as having one end free, and one end fixed. If reinforcement was required for the
hanger rod, it was selected based on the assumptions that the reinforcing angle was
carrying the entire compressive load, and that the reinforcing angle was equal to the
length of the hanger rod.
Introduction:
In a similar fashion, Euler’
s formula was used to determine the maximum allowable values
for the clamp locating dimensions L1 and L3. However, in this case L1 and L3 assumed to
be equal to each other, and their sum was set to be equal to the maximum un-reinforced
length of the hanger rod computed using Euler’
s formula with one end of the rod fixed and
the other end free. In determining the maximum value for the clamp spacing, L2, Euler’
s
formula was used assuming that both ends of the hanger rod were fixed at the clamps.
The horizontal seismic loads applied to the hanger rods are based on the Kinetics Noise
Control Horizontal Force Class, or Force Class, designations of I through VI. The
KHRC-A ROD STIFFENER DATA FOR 0°
A
30° - GENERAL
PAGE 1 OF 10
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A8.1.1
MEMBER
installation angle (A), as measured from the horizontal, was taken to be 30°, and will be
used to cover the range of installation angles from 0° to 30° inclusively. The Force Class
system ranges are shown below.
The maximum load in each Force Class was used with a Factor of Safety of 2:1 in
determining the maximum un-reinforced hanger rod length, the minimum angle size to be
used for the rod stiffener, and the values used for L1, L2, and L3.
Use of the KHRC-A Rod Stiffener Data Tables:
1.) Data Tables: There is a hanger rod stiffener selection data table for each Force
Class.
2.) Hanger Rod Sizes: The hanger rod sizes that may be used with the Kinetics
Noise Control model KHRC-A, and that are applicable for each Force Class are
listed across the top of each data table.
3.) Hanger Rod Length: The hanger rod lengths that are applicable are listed in the
left hand column of each table in
and 12 multiples. The maximum reinforced
hanger rod length for each Force Class is the last entry in this column.
4.) Rod Stiffener Requirement: Determine the appropriate Force Class for the
application. Select the column for the hanger rod size being used, and follow it
down to the hanger rod length being considered. If the word “Yes”is found in this
box, a hanger rod stiffener will be required. If, on the other hand, the word “No”is
found in the box, then a hanger rod stiffener is not required. If the hanger rod
length being used falls in between two of the tabulated rod lengths, use the larger
value for the hanger rod length.
5.) Minimum Stiffener Angle Size: The minimum reinforcement angle size for each
hanger rod length in each Force Class is listed in the right hand column of each
table. Use the minimum Stiffener Angle size that corresponds to the hanger rod
length used in step “4.)”.
6.) Maximum Installation Dimensions: The maximum allowable installation
dimensions, L1, L2, and L3, are tabulated by hanger rod size beneath the rod
stiffener selection data table for each Force Class.
7.) KHRC-A Clamp Kits: A minimum of two (2) Kinetics Noise Control model
KHRC-A clamps kits are required for each hanger rod stiffener installation. The
KHRC-A clamp kits should be spaced approximately
from each end of the rod
stiffener angle. The distance from where the hanger rod is attached to the
suspended component and the lower KHRC-A clamp kit must not exceed the value
for L1 listed for the Force Class and hanger rod size being used. If the spacing
A
30° - GENERAL
PAGE 2 OF 10
Force Class I: 0 lbs through 250 lbs
Force Class II: 251 lbs through 500 lbs
Force Class III: 501 lbs through 1,000 lbs
Force Class IV: 1,001 lbs through 2,000 lbs
Force Class V: 2,001 lbs through 5,000lbs
Force Class VI: 5,001 lbs through 10,000lbs
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A8.1.1
MEMBER
between the two KHRC-A clamp kits exceeds the value of L2, maximum allowable
spacing between clamps, listed for the Force Class and rod size for the application,
another KHRC-A clamp kit must be added between the original pair. Finally, the
distance from the upper KHRC-A clamp kit where the hanger rod attaches to the
structure, or isolation hanger, must not exceed the value listed for L3, based on the
Force Class and rod size being considered. Also note that the thumb screw should
be securely tightened. Pliers may be used after thumb screw is made finger tight.
HOLE #2 CONFIGURATION:
MIN. ANGLE: L1-3/4x1-3/4x3/16.
MIN. ROD: Ø3/8 UNC.
MIN. ANGLE: L1x1x1/8.
MAX. ANGLE: L2x2x3/8.
MIN. ROD: Ø1-1/4 UNC.
MAX. ANGLE: L1-1/2x1-1/2x1/4.
MIN. ROD: Ø1 UNC.
KINETICS
KINETICS
KHRC-A
KHRC-A
THUMB SCREW
BY KINETICS.
KHRC-A OUTER CLAMP
HALF BY KINETICS.
KHRC-A INNER CLAMP
HALF BY KINETICS.
CLEARNACE HOLE #1
THREADED HOLE #1
CLEARANCE HOLE #2
THREADED HOLE #2
Figure A8.1.1-1; Kinetics Noise Control Model KHRC-A.
A
30° - GENERAL
PAGE 3 OF 10
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DOCUMENT:
A8.1.1
MEMBER
L3
KINETICS
KHRC- A
MODEL KHRC-A
ADJUSTABLE
ANGLE STIFFENER
CLAMP BY KINETICS.
NUMBER REQUIRED
IS BASED ON HANGER
ROD SIZE & LENGTH
FOR EACH
FORCE CLASS &
INSTALLATION ANGLE
(A°) RANGE.
~1
KINETICS
KHRC- A
L
L2
A°
KINETICS
KHRC- A
~1
L1
HANGER ROD
BY OTHERS.
STIFFENER ANGLE
BY OTHERS.
SELECTION IS BASED
ON HANGER ROD SIZE
& LENGTH FOR EACH
FORCE CLASS AND
INSTALLATION
ANGLE (A°) RANGE.
Figure A8.1.1-2; Typical Hanger Rod Stiffener Installation.
A
30° - GENERAL
PAGE 4 OF 10
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DOCUMENT:
A8.1.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
No
No
No
No
No
No
No
------------------------
12
Yes
No
No
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
24
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
30
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
36
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
48
Yes
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
60
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
72
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
84
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
96
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
108
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
120
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
132
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
144
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
156
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
168
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
180
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
192
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
204
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
216
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
228
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
229 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
3/8
1/2
5/8
3/4
7/8
1-1/4
ROD ROD ROD ROD ROD ROD ROD
Max. L1 =
4
8
14
21
29
38
63
Max. L2 =
17
34
56
84
118
155
155
Max. L3 =
4
8
14
21
29
38
63
A
30° - FORCE CLASS I
PAGE 5 OF 10
Rod
3/8
Length ( ) Rod
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DOCUMENT:
A8.1.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
No
No
No
No
No
No
No
------------------------
12
Yes
No
No
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
30
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
36
Yes
Yes
Yes
Yes
No
No
No
1-1/8 x 1-1/8 x 1/8
48
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
72
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
84
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
96
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
108
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
120
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
132
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
144
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
156
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
162 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
1/2
5/8
3/4
7/8
1-1/4
3/8
Max. L1 =
3
5
9
14
20
27
44
Max. L2 =
12
23
39
59
83
109
109
Max. L3 =
3
5
9
14
20
27
44
A
30° - FORCE CLASS II
PAGE 6 OF 10
Rod
3/8
Length ( ) Rod
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DOCUMENT:
A8.1.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
30
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
36
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2x 1-1/2 x 1/4
72
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
84
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
96
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
108
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
114 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
1/2
5/8
3/4
7/8
1-1/4
3/8
Max. L1 =
2
4
6
10
14
19
31
Max. L2 =
8
16
27
41
58
77
77
Max. L3 =
2
4
6
10
14
19
31
A
30° - FORCE CLASS III
PAGE 7 OF 10
Rod
3/8
Length ( ) Rod
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DOCUMENT:
A8.1.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
Yes
No
No
No
1-1/8 x 1-1/8 x 1/8
24
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
30
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
36
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
72
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
81 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
3/8
Length ( ) Rod
3/8
1/2
5/8
3/4
7/8
1-1/4
Max. L1 =
1
2
4
7
10
13
22
Max. L2 =
5
11
18
28
40
54
54
Max. L3 =
1
2
4
7
10
13
22
A
30° - FORCE CLASS IV
PAGE 8 OF 10
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DOCUMENT:
A8.1.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
No
No
No
1-1/8 x 1-1/8 x 1/8
18
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 3/16
24
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
30
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
36
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
51 Max.
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
5/8
3/4
7/8
1-1/4
1/2
ROD ROD ROD ROD ROD ROD
Max. L1 =
1
2
4
6
8
13
Max. L2 =
6
11
17
25
33
33
Max. L3 =
1
2
4
6
8
13
A
30° - FORCE CLASS V
PAGE 9 OF 10
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DOCUMENT:
A8.1.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
Yes
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
18
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
24
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
30
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
36 Max.
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
5/8
3/4
7/8
1-1/4
1/2
Max. L1 =
1
1
3
4
5
9
Max. L2 =
4
7
12
17
23
23
Max. L3 =
1
1
3
4
5
9
A
30° - FORCE CLASS VI
PAGE 10 OF 10
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DOCUMENT:
A8.1.1
MEMBER
KHRC-A Rod Stiffener Data for 30° < A
45°
kits.
Buckling Analysis:
result.
Introduction:
s
KHRC-A ROD STIFFENER DATA FOR 30° < A
45° - GENERAL
PAGE 1 OF 10
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DOCUMENT:
A8.2.1
MEMBER
Class.
45° - GENERAL
PAGE 2 OF 10
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DOCUMENT:
A8.2.1
MEMBER
MIN. ANGLE: L1-3/4x1-3/4x3/16.
MAX. ANGLE: L1-1/2x1-1/2x1/4.
MIN. ROD: Ø1 UNC.
KINETICS
KINETICS
KHRC-A
KHRC-A
THUMB SCREW
BY KINETICS.
KHRC-A OUTER CLAMP
HALF BY KINETICS.
KHRC-A INNER CLAMP
HALF BY KINETICS.
CLEARNACE HOLE #1
THREADED HOLE #1
CLEARANCE HOLE #2
THREADED HOLE #2
45° - GENERAL
PAGE 3 OF 10
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DOCUMENT:
A8.2.1
MEMBER
L3
KINETICS
KHRC- A
MODEL KHRC-A
ADJUSTABLE
ANGLE STIFFENER
CLAMP BY KINETICS.
NUMBER REQUIRED
IS BASED ON HANGER
ROD SIZE & LENGTH
FOR EACH
FORCE CLASS &
INSTALLATION ANGLE
(A°) RANGE.
~1
KINETICS
KHRC- A
L
L2
A°
KINETICS
KHRC- A
~1
L1
HANGER ROD
BY OTHERS.
STIFFENER ANGLE
BY OTHERS.
SELECTION IS BASED
ON HANGER ROD SIZE
& LENGTH FOR EACH
FORCE CLASS AND
INSTALLATION
ANGLE (A°) RANGE.
45° - GENERAL
PAGE 4 OF 10
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DOCUMENT:
A8.2.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
No
No
No
No
No
No
No
------------------------
12
Yes
No
No
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
30
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
36
Yes
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
48
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 3/16
72
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
84
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
96
Yes
Yes
Yes
Yes
Yes
Yes
No
1-3/4 x 1-3/4 x 3/16
108
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
120
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
132
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
144
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
156
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
168
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
174 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
3/8
1/2
5/8
3/4
7/8
1-1/4
Max. L1 =
3
6
10
15
22
29
47
Max. L2 =
13
25
42
63
89
117
117
Max. L3 =
3
6
10
15
22
29
47
PAGE 5 OF 10
Rod
3/8
Length ( ) Rod
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DOCUMENT:
A8.2.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
30
Yes
Yes
Yes
Yes
No
No
No
1-1/8 x 1-1/8 x 1/8
36
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
60
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
72
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
84
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
96
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
108
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
120
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
123 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
1/2
5/8
3/4
7/8
1-1/4
3/8
Max. L1 =
2
4
7
11
15
20
33
Max. L2 =
8
17
29
44
62
82
82
Max. L3 =
2
4
7
11
15
20
20
PAGE 6 OF 10
Rod
3/8
Length ( ) Rod
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DOCUMENT:
A8.2.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
30
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 3/16
36
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
No
1-3/4 x 1-3/4 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
72
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
84
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
87 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
3/8
Length ( ) Rod
1/2
5/8
3/4
7/8
1-1/4
3/8
Max. L1 =
1
3
5
7
10
17
23
Max. L2 =
5
12
20
31
43
58
58
Max. L3 =
1
3
5
7
10
14
23
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DOCUMENT:
A8.2.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
24
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
30
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
36
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
60
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
61 Max.
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
5/8
3/4
7/8
1-1/4
1/2
Max. L1 =
2
3
5
7
10
16
Max. L2 =
8
13
21
30
40
40
Max. L3 =
2
3
5
7
10
16
PAGE 8 OF 10
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DOCUMENT:
A8.2.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
Yes
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
18
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
24
Yes
Yes
Yes
Yes
Yes
No
1-3/4 x 1-3/4 x 1/4
30
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
36
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
39 Max.
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
1/2
5/8
3/4
7/8
1-1/4
Max. L1 =
1
2
3
4
6
10
Max. L2 =
4
8
13
18
25
41
Max. L3 =
1
2
3
4
6
10
PAGE 9 OF 10
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DOCUMENT:
A8.2.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
6
Yes
Yes
Yes
12
Yes
Yes
18
Yes
24
27 Max.
Mounting
Dim. ( )
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
No
No
No
1-1/8 x 1-1/8 x 1/8
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Rod
Length ( )
5/8
3/4
7/8
1-1/4
1/2
Max. L1 =
1
2
4
6
8
7
Max. L2 =
2
5
8
12
17
28
Max. L3 =
1
2
4
6
8
7
PAGE 10 OF 10
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DOCUMENT:
A8.2.1
MEMBER
KHRC-A Rod Stiffener Data for 45° < A
60°
kits.
Buckling Analysis:
result.
Introduction:
s
60° - GENERAL
PAGE 1 OF 10
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DOCUMENT:
A8.3.1
MEMBER
Class.
60° - GENERAL
PAGE 2 OF 10
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DOCUMENT:
A8.3.1
MEMBER
MIN. ANGLE: L1-3/4x1-3/4x3/16.
MAX. ANGLE: L1-1/2x1-1/2x1/4.
MIN. ROD: Ø1 UNC.
KINETICS
KINETICS
KHRC-A
KHRC-A
THUMB SCREW
BY KINETICS.
KHRC-A OUTER CLAMP
HALF BY KINETICS.
KHRC-A INNER CLAMP
HALF BY KINETICS.
CLEARNACE HOLE #1
THREADED HOLE #1
CLEARANCE HOLE #2
THREADED HOLE #2
60° - GENERAL
PAGE 3 OF 10
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DOCUMENT:
A8.3.1
MEMBER
L3
KINETICS
KHRC- A
MODEL KHRC-A
ADJUSTABLE
ANGLE STIFFENER
CLAMP BY KINETICS.
NUMBER REQUIRED
IS BASED ON HANGER
ROD SIZE & LENGTH
FOR EACH
FORCE CLASS &
INSTALLATION ANGLE
(A°) RANGE.
~1
KINETICS
KHRC- A
L
L2
A°
KINETICS
KHRC- A
~1
L1
HANGER ROD
BY OTHERS.
STIFFENER ANGLE
BY OTHERS.
SELECTION IS BASED
ON HANGER ROD SIZE
& LENGTH FOR EACH
FORCE CLASS AND
INSTALLATION
ANGLE (A°) RANGE.
60° - GENERAL
PAGE 4 OF 10
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DOCUMENT:
A8.3.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
No
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
30
Yes
Yes
Yes
Yes
No
No
No
1-1/8 x 1-1/8 x 1/8
36
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
42
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
54
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
66
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
72
Yes
Yes
Yes
Yes
Yes
Yes
No
1-3/4 x 1-3/4 x 3/16
78
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
84
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
90
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
96
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
102
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
108
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
114
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
120
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
126
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
132 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
1/2
5/8
3/4
7/8
1-1/4
3/8
Max. L1 =
2
4
7
12
16
22
36
Max. L2 =
9
19
31
48
67
89
89
Max. L3 =
2
4
7
12
16
22
36
PAGE 5 OF 10
Rod
3/8
Length ( ) Rod
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DOCUMENT:
A8.3.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
Yes
No
No
No
1 x 1 x 1/8
24
Yes
Yes
Yes
Yes
No
No
No
1-1/4 x 1-1/4 x 3/16
30
Yes
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
36
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
42
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
48
Yes
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
54
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
60
Yes
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
66
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
72
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
78
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
84
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
90
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
93 Max.
Yes
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
3/8
Length ( ) Rod
3/8
1/2
5/8
3/4
7/8
1-1/4
Max. L1 =
1
3
5
8
11
15
25
Max. L2 =
6
13
21
33
47
62
62
Max. L3 =
1
3
5
8
11
15
25
PAGE 6 OF 10
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DOCUMENT:
A8.3.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
No
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
No
No
No
No
1 x 1 x 1/8
18
Yes
Yes
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
24
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
30
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
36
Yes
Yes
Yes
Yes
Yes
No
1-3/4 x 1-3/4 x 3/16
42
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
48
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/16
54
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
60
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
66 Max.
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
5/8
3/4
7/8
1-1/4
1/2
Max. L1 =
2
3
5
8
10
17
Max. L2 =
8
15
23
32
43
43
Max. L3 =
2
3
5
8
10
17
PAGE 7 OF 10
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DOCUMENT:
A8.3.1
MEMBER
1/2
Rod
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
Yes
No
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
No
No
No
1-1/4 x 1-1/4 x 3/16
18
Yes
Yes
Yes
Yes
Yes
No
1-1/4 x 1-1/4 x 1/4
24
Yes
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 1/4
30
Yes
Yes
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 1/4
36
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
42
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 5/16
46 Max.
Yes
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
5/8
3/4
7/8
1-1/4
1/2
Max. L1 =
1
2
3
5
7
12
Max. L2 =
5
10
15
22
30
50
Max. L3 =
1
2
3
5
7
12
PAGE 8 OF 10
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DOCUMENT:
A8.3.1
MEMBER
5/8
Rod
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
Yes
No
No
No
1 x 1 x 1/8
12
Yes
Yes
Yes
Yes
No
1-1/2 x 1-1/2 x 3/16
18
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/8
24
Yes
Yes
Yes
Yes
Yes
2 x 2 x 1/4
29 Max.
Yes
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
3/4
7/8
1-1/4
5/8
ROD ROD ROD ROD ROD
Max. L1 =
1
2
3
4
7
Max. L2 =
5
9
13
18
18
Max. L3 =
1
2
3
4
7
PAGE 9 OF 10
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DOCUMENT:
A8.3.1
MEMBER
3/4
Rod
7/8
Rod
Rod
1-1/4
Rod
Minimum Rod
Stiffener Angle
6
Yes
Yes
No
No
1-1/4 x 1-1/4 x 3/16
12
Yes
Yes
Yes
Yes
1-3/4 x 1-3/4 x 3/16
18
Yes
Yes
Yes
Yes
2 x 2 x 5/16
20 Max.
Yes
Yes
Yes
Yes
2 x 2 x 3/8
Mounting
Dim. ( )
Rod
Length ( )
3/4
7/8
1-1/4
ROD ROD ROD ROD
Max. L1 =
1
2
3
5
Max. L2 =
6
9
12
21
Max. L3 =
1
2
3
5
PAGE 10 OF 10
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DOCUMENT:
A8.3.1
MEMBER
EMT – Electrical Conduit Data
Table A9.1.1-1; EMT Conduit – 40% Copper Fill.
Conduit
Size
(in)
Conduit
O.D.
(in)
Conduit
I.D.
(in)
Conduit
Weight
Empty
(lb/ft)
Copper
Weight
(lb/ft)
Conduit
+
Copper
(lb/ft)
1/2
0.706
0.622
0.30
0.47
0.77
3/4
0.922
0.824
0.46
0.82
1.28
1
1.163
1.049
0.67
1.34
2.01
1-1/4
1.510
1.380
1.00
2.31
3.31
1-1/2
1.740
1.610
1.16
3.15
4.31
2
2.197
2.067
1.48
5.19
6.67
2-1/2
2.875
2.731
2.15
9.05
11.20
3
3.500
3.356
2.63
13.67
16.30
3-1/2
4.000
3.834
3.47
17.84
21.31
4
4.500
4.334
3.91
22.80
26.71
EMT – ELECTRICAL CONDUIT DATA
PAGE 1 OF 3
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DOCUMENT:
A9.1.1
MEMBER
I
(in4)
Conduit
+
Copper
(lb/ft)
Maximum
Support
Spacing
(ft)1
0.622
0.0048
0.77
8.91
0.922
0.824
0.0128
1.28
9.88
1
1.163
1.049
0.0672
2.01
16.08
1-1/4
1.510
1.380
0.0772
3.31
11.12
1-1/2
1.740
1.610
0.1201
4.31
11.32
2
2.197
2.067
0.2476
6.67
11.63
2-1/2
2.875
2.731
0.6231
11.20
13.91
3
3.500
3.356
1.1395
16.30
14.13
3-1/2
4.000
3.834
1.9597
21.31
14.38
4
4.500
4.334
2.8098
26.71
14.50
Conduit
Size
(in)
O.D.
(in)
I.D.
(in)
1/2
0.706
3/4
1) Determined by assuming that the conduit was a beam with fixed ends and an evenly
distributed load equal to the weight of the conduit and a 40% fill of copper. The conduit
material was assumed to be equal to low carbon commercial quality steel sheet with a yield
stress of 40,000 psi – 50,000 psi.
Table A9.1.1-2; EMT Conduit Maximum Support Spacing - Bending.
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A9.1.1
MEMBER
Conduit
Size
(in)
I
(in4)
Force
Class
I2, 8
Force
Class
II3, 8
Force
Class
III4, 8
Force
Class
IV5, 8
Force
Class
V6, 8
Force
Class
VI7, 8
1/2
0.0048
4.44
3.14
2.22
1.57
0.99
0.70
3/4
0.0128
7.26
5.13
3.63
2.57
1.62
1.15
1
0.0672
16.62
11.75
8.31
5.88
3.72
2.63
1-1/4
0.0772
17.82
12.60
8.91
6.30
3.98
2.82
1-1/2
0.1201
22.22
15.71
11.11
7.86
4.97
3.51
2
0.2476
31.91
22.56
15.95
11.28
7.14
5.05
2-1/2
0.6231
50.62
35.79
25.31
17.90
11.32
8.00
3
1.1395
68.45
48.40
34.23
24.20
15.31
10.82
3-1/2
1.9597
89.77
63.48
44.89
31.74
20.07
14.19
4
2.8098
107.49
76.01
53.75
38.00
24.04
17.00
1) The Maximum Support Spacing based on Buckling relies on Euler’s Theory of Column
Buckling. There is a Factor of Safety of 2:1 with respect to the applied Horizontal Seismic
Load. Both ends of the conduit are assumed to be fixed, and the conservative end condition
factor of 1.00 was used.
2) Horizontal Force Class I: 0 lbs. Horizontal Seismic Force 250 lbs.
3) Horizontal Force Class II: 251 lbs. Horizontal Seismic Force 500 lbs.
4) Horizontal Force Class III: 501 lbs. Horizontal Seismic Force 1,000 lbs.
5) Horizontal Force Class IV: 1,001 lbs. Horizontal Seismic Force 2,000 lbs.
6) Horizontal Force Class V: 2,001 lbs. Horizontal Seismic Force 5,000 lbs.
7) Horizontal Force Class VI: 5,001 lbs. Horizontal Seismic Force 10,000 lbs.
8) For Actual Horizontal Forces that fall between the minimum and maximum values for a
given Horizontal Force Class, the Maximum Support Spacing for Buckling may be
determined by multiplying the appropriate value from Table A9.1.1-3 by the following factor.
Table A9.1.1-3; EMT Conduit Maximum Support Spacing – Buckling1.
KS = [ Upper Horizontal Force Class Limit / Actual Horizontal Seismic Force ]1/2
Example: 1/2 EMT with and Actual Horizontal Seismic Force of 50 lbs (Force Class I Range).
KS = [ 250 lbs. / 50lbs. ]1/2 = 2.24
The Actual Maximum Support Spacing = 2.24 x 4.44 ft. = 9.95 ft.
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A9.1.1
MEMBER
IMC – Electrical Conduit Data
Table A9.2.1-1; IMC Conduit – 40% Copper Fill.
Conduit
Size
(in)
Conduit
O.D.
(in)
Conduit
I.D.
(in)
Conduit
Weight
Empty
(lb/ft)
Copper
Weight
(lb/ft)
Conduit
+
Copper
(lb/ft)
1/2
0.815
0.675
0.56
0.55
1.11
3/4
1.029
0.879
0.76
0.94
1.70
1
1.290
1.120
1.09
1.52
2.61
1-1/4
1.638
1.468
1.41
2.62
4.03
1-1/2
1.883
1.703
1.72
3.52
5.24
2
2.360
2.170
2.30
5.72
8.02
2-1/2
2.857
2.557
4.33
7.94
12.27
3
3.476
3.196
4.98
12.40
17.38
3-1/2
3.971
3.691
5.72
16.54
22.26
4
4.466
4.186
6.46
21.27
27.73
IMC – ELECTRICAL CONDUIT DATA
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A9.2.1
MEMBER
I
(in4)
Conduit
+
Copper
(lb/ft)
Maximum
Support
Spacing
(ft)1
0.675
0.0115
1.11
11.27
1.029
0.879
0.0257
1.70
12.12
1
1.290
1.120
0.1066
2.61
17.79
1-1/4
1.638
1.468
0.1254
4.03
13.78
1-1/2
1.883
1.703
0.2042
5.24
14.39
2
2.360
2.170
0.4343
8.02
15.15
2-1/2
2.857
2.557
1.1721
12.27
18.29
3
3.476
3.196
2.0447
17.38
18.40
3-1/2
3.971
3.691
3.0953
22.26
17.75
4
4.466
4.186
4.4556
27.73
17.99
Conduit
Size
(in)
O.D.
(in)
I.D.
(in)
1/2
0.815
3/4
material was assumed to be equal to cold rolled carbon steel sheet with a yield stress of
45,000 psi – 50,000psi.
Table A9.2.1-2; IMC Conduit Maximum Support Spacing - Bending.
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A9.2.1
MEMBER
Conduit
Size
(in)
I
(in4)
Force
Class
I2, 8
Force
Class
II3, 8
Force
Class
III4, 8
Force
Class
IV5, 8
Force
Class
V6, 8
Force
Class
VI7, 8
1/2
0.0115
6.88
4.86
3.44
2.43
1.54
1.09
3/4
0.0257
10.28
7.27
5.14
3.63
2.30
1.63
1
0.1066
20.94
14.80
10.47
7.40
4.68
3.31
1-1/4
0.1254
22.71
16.06
11.35
8.03
5.08
3.59
1-1/2
0.2042
28.98
20.49
14.49
10.25
6.48
4.58
2
0.4343
42.26
29.88
21.13
14.94
9.45
6.68
2-1/2
1.1721
69.43
49.09
34.71
24.55
15.52
10.98
3
2.0447
91.70
64.84
45.85
32.42
20.50
14.50
3-1/2
3.0953
112.82
79.78
56.41
39.89
25.23
17.84
4
4.4556
135.36
95.72
67.68
47.86
30.27
21.40
Table A9.2.1-3; IMC Conduit Maximum Support Spacing – Buckling1.
KS = [ 250 lbs. / 50lbs. ]1/2 = 2.24
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A9.2.1
MEMBER
Rigid – Electrical Conduit Data
Table A9.3.1-1; Rigid Conduit – 40% Copper Fill.
Conduit
Size
(in)
Conduit
O.D.
(in)
Conduit
I.D.
(in)
Conduit
Weight
Empty
(lb/ft)
Copper
Weight
(lb/ft)
Conduit
+
Copper
(lb/ft)
1/2
0.840
0.632
0.82
0.48
1.30
3/4
1.050
0.836
1.08
0.85
1.93
1
1.315
1.063
1.60
1.37
2.97
1-1/4
1.660
1.394
2.17
2.36
4.53
1-1/2
1.900
1.624
2.59
3.20
5.79
2
2.375
2.083
3.47
5.27
8.74
2-1/2
2.875
2.489
5.52
7.52
13.04
3
3.500
3.090
7.21
11.59
18.80
3-1/2
4.000
3.570
8.68
15.47
24.15
4
4.500
4.050
10.26
19.91
30.17
5
5.563
5.073
13.90
31.24
45.14
6
6.625
6.093
18.05
45.07
63.12
RIGID – ELECTRICAL CONDUIT DATA
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A9.3.1
MEMBER
Conduit
Size
(in)
O.D.
(in)
I.D.
(in)
I
(in4)
Conduit
+
Copper
(lb/ft)
Maximum
Support
Spacing
(ft)1
1/2
0.840
0.632
0.0166
1.30
12.33
3/4
1.050
0.836
0.0357
1.93
13.27
1
1.315
1.063
0.1228
2.97
17.73
1-1/4
1.660
1.394
0.1874
4.53
15.79
1-1/2
1.900
1.624
0.2983
5.79
16.47
2
2.375
2.083
0.6377
8.74
17.53
2-1/2
2.875
2.489
1.4697
13.04
19.80
3
3.500
3.090
2.8911
18.80
19.89
3-1/2
4.000
3.570
4.5930
24.15
20.69
4
4.500
4.050
6.9223
30.17
21.42
5
5.563
5.073
14.501
45.14
22.80
6
6.625
6.093
26.907
63.12
24.06
material was assumed to be equal to cold rolled carbon steel sheet with a yield stress of
45,000 psi – 50,000psi.
Table A9.3.1-2; Rigid Conduit Maximum Support Spacing - Bending.
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A9.3.1
MEMBER
Conduit
Size
(in)
I
(in4)
Force
Class
I2, 8
Force
Class
II3, 8
Force
Class
III4, 8
Force
Class
IV5, 8
Force
Class
V6, 8
Force
Class
VI7, 8
1/2
0.0166
8.26
5.84
4.13
2.92
1.85
1.31
3/4
0.0357
12.12
8.57
6.06
4.28
2.71
1.92
1
0.1228
22.47
15.89
11.24
7.95
5.02
3.55
1-1/4
0.1874
27.76
19.63
13.88
9.81
6.21
4.39
1-1/2
0.2983
35.02
24.77
17.51
12.38
7.83
5.54
2
0.6377
51.21
36.21
25.60
18.11
11.45
8.10
2-1/2
1.4697
77.74
54.97
38.87
27.49
17.38
12.29
3
2.8911
109.04
77.10
54.52
38.55
24.38
17.24
3-1/2
4.5930
137.43
97.18
68.72
48.59
30.73
21.73
4
6.9223
168.72
119.30
84.36
59.65
37.73
26.68
5
14.501
244.20
172.67
122.10
86.34
54.60
38.61
6
26.907
332.64
235.21
166.32
117.61
74.38
52.60
Table A9.3.1-3; Rigid Conduit Maximum Support Spacing – Buckling1.
KS = [ 250 lbs. / 50lbs. ]
1/2
= 2.24
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A9.3.1
MEMBER

kinetics - STRUCTURAL ENGINEERING FORUM OF INDIA

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